1 /* 2 * CDDL HEADER START 3 * 4 * The contents of this file are subject to the terms of the 5 * Common Development and Distribution License (the "License"). 6 * You may not use this file except in compliance with the License. 7 * 8 * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE 9 * or http://www.opensolaris.org/os/licensing. 10 * See the License for the specific language governing permissions 11 * and limitations under the License. 12 * 13 * When distributing Covered Code, include this CDDL HEADER in each 14 * file and include the License file at usr/src/OPENSOLARIS.LICENSE. 15 * If applicable, add the following below this CDDL HEADER, with the 16 * fields enclosed by brackets "[]" replaced with your own identifying 17 * information: Portions Copyright [yyyy] [name of copyright owner] 18 * 19 * CDDL HEADER END 20 */ 21 /* 22 * Copyright 2008 Sun Microsystems, Inc. All rights reserved. 23 * Use is subject to license terms. 24 */ 25 26 #pragma ident "%Z%%M% %I% %E% SMI" 27 28 /* 29 * Kernel memory allocator, as described in the following two papers and a 30 * statement about the consolidator: 31 * 32 * Jeff Bonwick, 33 * The Slab Allocator: An Object-Caching Kernel Memory Allocator. 34 * Proceedings of the Summer 1994 Usenix Conference. 35 * Available as /shared/sac/PSARC/1994/028/materials/kmem.pdf. 36 * 37 * Jeff Bonwick and Jonathan Adams, 38 * Magazines and vmem: Extending the Slab Allocator to Many CPUs and 39 * Arbitrary Resources. 40 * Proceedings of the 2001 Usenix Conference. 41 * Available as /shared/sac/PSARC/2000/550/materials/vmem.pdf. 42 * 43 * kmem Slab Consolidator Big Theory Statement: 44 * 45 * 1. Motivation 46 * 47 * As stated in Bonwick94, slabs provide the following advantages over other 48 * allocation structures in terms of memory fragmentation: 49 * 50 * - Internal fragmentation (per-buffer wasted space) is minimal. 51 * - Severe external fragmentation (unused buffers on the free list) is 52 * unlikely. 53 * 54 * Segregating objects by size eliminates one source of external fragmentation, 55 * and according to Bonwick: 56 * 57 * The other reason that slabs reduce external fragmentation is that all 58 * objects in a slab are of the same type, so they have the same lifetime 59 * distribution. The resulting segregation of short-lived and long-lived 60 * objects at slab granularity reduces the likelihood of an entire page being 61 * held hostage due to a single long-lived allocation [Barrett93, Hanson90]. 62 * 63 * While unlikely, severe external fragmentation remains possible. Clients that 64 * allocate both short- and long-lived objects from the same cache cannot 65 * anticipate the distribution of long-lived objects within the allocator's slab 66 * implementation. Even a small percentage of long-lived objects distributed 67 * randomly across many slabs can lead to a worst case scenario where the client 68 * frees the majority of its objects and the system gets back almost none of the 69 * slabs. Despite the client doing what it reasonably can to help the system 70 * reclaim memory, the allocator cannot shake free enough slabs because of 71 * lonely allocations stubbornly hanging on. Although the allocator is in a 72 * position to diagnose the fragmentation, there is nothing that the allocator 73 * by itself can do about it. It only takes a single allocated object to prevent 74 * an entire slab from being reclaimed, and any object handed out by 75 * kmem_cache_alloc() is by definition in the client's control. Conversely, 76 * although the client is in a position to move a long-lived object, it has no 77 * way of knowing if the object is causing fragmentation, and if so, where to 78 * move it. A solution necessarily requires further cooperation between the 79 * allocator and the client. 80 * 81 * 2. Move Callback 82 * 83 * The kmem slab consolidator therefore adds a move callback to the 84 * allocator/client interface, improving worst-case external fragmentation in 85 * kmem caches that supply a function to move objects from one memory location 86 * to another. In a situation of low memory kmem attempts to consolidate all of 87 * a cache's slabs at once; otherwise it works slowly to bring external 88 * fragmentation within the 1/8 limit guaranteed for internal fragmentation, 89 * thereby helping to avoid a low memory situation in the future. 90 * 91 * The callback has the following signature: 92 * 93 * kmem_cbrc_t move(void *old, void *new, size_t size, void *user_arg) 94 * 95 * It supplies the kmem client with two addresses: the allocated object that 96 * kmem wants to move and a buffer selected by kmem for the client to use as the 97 * copy destination. The callback is kmem's way of saying "Please get off of 98 * this buffer and use this one instead." kmem knows where it wants to move the 99 * object in order to best reduce fragmentation. All the client needs to know 100 * about the second argument (void *new) is that it is an allocated, constructed 101 * object ready to take the contents of the old object. When the move function 102 * is called, the system is likely to be low on memory, and the new object 103 * spares the client from having to worry about allocating memory for the 104 * requested move. The third argument supplies the size of the object, in case a 105 * single move function handles multiple caches whose objects differ only in 106 * size (such as zio_buf_512, zio_buf_1024, etc). Finally, the same optional 107 * user argument passed to the constructor, destructor, and reclaim functions is 108 * also passed to the move callback. 109 * 110 * 2.1 Setting the Move Callback 111 * 112 * The client sets the move callback after creating the cache and before 113 * allocating from it: 114 * 115 * object_cache = kmem_cache_create(...); 116 * kmem_cache_set_move(object_cache, object_move); 117 * 118 * 2.2 Move Callback Return Values 119 * 120 * Only the client knows about its own data and when is a good time to move it. 121 * The client is cooperating with kmem to return unused memory to the system, 122 * and kmem respectfully accepts this help at the client's convenience. When 123 * asked to move an object, the client can respond with any of the following: 124 * 125 * typedef enum kmem_cbrc { 126 * KMEM_CBRC_YES, 127 * KMEM_CBRC_NO, 128 * KMEM_CBRC_LATER, 129 * KMEM_CBRC_DONT_NEED, 130 * KMEM_CBRC_DONT_KNOW 131 * } kmem_cbrc_t; 132 * 133 * The client must not explicitly kmem_cache_free() either of the objects passed 134 * to the callback, since kmem wants to free them directly to the slab layer 135 * (bypassing the per-CPU magazine layer). The response tells kmem which of the 136 * objects to free: 137 * 138 * YES: (Did it) The client moved the object, so kmem frees the old one. 139 * NO: (Never) The client refused, so kmem frees the new object (the 140 * unused copy destination). kmem also marks the slab of the old 141 * object so as not to bother the client with further callbacks for 142 * that object as long as the slab remains on the partial slab list. 143 * (The system won't be getting the slab back as long as the 144 * immovable object holds it hostage, so there's no point in moving 145 * any of its objects.) 146 * LATER: The client is using the object and cannot move it now, so kmem 147 * frees the new object (the unused copy destination). kmem still 148 * attempts to move other objects off the slab, since it expects to 149 * succeed in clearing the slab in a later callback. The client 150 * should use LATER instead of NO if the object is likely to become 151 * movable very soon. 152 * DONT_NEED: The client no longer needs the object, so kmem frees the old along 153 * with the new object (the unused copy destination). This response 154 * is the client's opportunity to be a model citizen and give back as 155 * much as it can. 156 * DONT_KNOW: The client does not know about the object because 157 * a) the client has just allocated the object and not yet put it 158 * wherever it expects to find known objects 159 * b) the client has removed the object from wherever it expects to 160 * find known objects and is about to free it, or 161 * c) the client has freed the object. 162 * In all these cases (a, b, and c) kmem frees the new object (the 163 * unused copy destination) and searches for the old object in the 164 * magazine layer. If found, the object is removed from the magazine 165 * layer and freed to the slab layer so it will no longer hold the 166 * slab hostage. 167 * 168 * 2.3 Object States 169 * 170 * Neither kmem nor the client can be assumed to know the object's whereabouts 171 * at the time of the callback. An object belonging to a kmem cache may be in 172 * any of the following states: 173 * 174 * 1. Uninitialized on the slab 175 * 2. Allocated from the slab but not constructed (still uninitialized) 176 * 3. Allocated from the slab, constructed, but not yet ready for business 177 * (not in a valid state for the move callback) 178 * 4. In use (valid and known to the client) 179 * 5. About to be freed (no longer in a valid state for the move callback) 180 * 6. Freed to a magazine (still constructed) 181 * 7. Allocated from a magazine, not yet ready for business (not in a valid 182 * state for the move callback), and about to return to state #4 183 * 8. Deconstructed on a magazine that is about to be freed 184 * 9. Freed to the slab 185 * 186 * Since the move callback may be called at any time while the object is in any 187 * of the above states (except state #1), the client needs a safe way to 188 * determine whether or not it knows about the object. Specifically, the client 189 * needs to know whether or not the object is in state #4, the only state in 190 * which a move is valid. If the object is in any other state, the client should 191 * immediately return KMEM_CBRC_DONT_KNOW, since it is unsafe to access any of 192 * the object's fields. 193 * 194 * Note that although an object may be in state #4 when kmem initiates the move 195 * request, the object may no longer be in that state by the time kmem actually 196 * calls the move function. Not only does the client free objects 197 * asynchronously, kmem itself puts move requests on a queue where thay are 198 * pending until kmem processes them from another context. Also, objects freed 199 * to a magazine appear allocated from the point of view of the slab layer, so 200 * kmem may even initiate requests for objects in a state other than state #4. 201 * 202 * 2.3.1 Magazine Layer 203 * 204 * An important insight revealed by the states listed above is that the magazine 205 * layer is populated only by kmem_cache_free(). Magazines of constructed 206 * objects are never populated directly from the slab layer (which contains raw, 207 * unconstructed objects). Whenever an allocation request cannot be satisfied 208 * from the magazine layer, the magazines are bypassed and the request is 209 * satisfied from the slab layer (creating a new slab if necessary). kmem calls 210 * the object constructor only when allocating from the slab layer, and only in 211 * response to kmem_cache_alloc() or to prepare the destination buffer passed in 212 * the move callback. kmem does not preconstruct objects in anticipation of 213 * kmem_cache_alloc(). 214 * 215 * 2.3.2 Object Constructor and Destructor 216 * 217 * If the client supplies a destructor, it must be valid to call the destructor 218 * on a newly created object (immediately after the constructor). 219 * 220 * 2.4 Recognizing Known Objects 221 * 222 * There is a simple test to determine safely whether or not the client knows 223 * about a given object in the move callback. It relies on the fact that kmem 224 * guarantees that the object of the move callback has only been touched by the 225 * client itself or else by kmem. kmem does this by ensuring that none of the 226 * cache's slabs are freed to the virtual memory (VM) subsystem while a move 227 * callback is pending. When the last object on a slab is freed, if there is a 228 * pending move, kmem puts the slab on a per-cache dead list and defers freeing 229 * slabs on that list until all pending callbacks are completed. That way, 230 * clients can be certain that the object of a move callback is in one of the 231 * states listed above, making it possible to distinguish known objects (in 232 * state #4) using the two low order bits of any pointer member (with the 233 * exception of 'char *' or 'short *' which may not be 4-byte aligned on some 234 * platforms). 235 * 236 * The test works as long as the client always transitions objects from state #4 237 * (known, in use) to state #5 (about to be freed, invalid) by setting the low 238 * order bit of the client-designated pointer member. Since kmem only writes 239 * invalid memory patterns, such as 0xbaddcafe to uninitialized memory and 240 * 0xdeadbeef to freed memory, any scribbling on the object done by kmem is 241 * guaranteed to set at least one of the two low order bits. Therefore, given an 242 * object with a back pointer to a 'container_t *o_container', the client can 243 * test 244 * 245 * container_t *container = object->o_container; 246 * if ((uintptr_t)container & 0x3) { 247 * return (KMEM_CBRC_DONT_KNOW); 248 * } 249 * 250 * Typically, an object will have a pointer to some structure with a list or 251 * hash where objects from the cache are kept while in use. Assuming that the 252 * client has some way of knowing that the container structure is valid and will 253 * not go away during the move, and assuming that the structure includes a lock 254 * to protect whatever collection is used, then the client would continue as 255 * follows: 256 * 257 * // Ensure that the container structure does not go away. 258 * if (container_hold(container) == 0) { 259 * return (KMEM_CBRC_DONT_KNOW); 260 * } 261 * mutex_enter(&container->c_objects_lock); 262 * if (container != object->o_container) { 263 * mutex_exit(&container->c_objects_lock); 264 * container_rele(container); 265 * return (KMEM_CBRC_DONT_KNOW); 266 * } 267 * 268 * At this point the client knows that the object cannot be freed as long as 269 * c_objects_lock is held. Note that after acquiring the lock, the client must 270 * recheck the o_container pointer in case the object was removed just before 271 * acquiring the lock. 272 * 273 * When the client is about to free an object, it must first remove that object 274 * from the list, hash, or other structure where it is kept. At that time, to 275 * mark the object so it can be distinguished from the remaining, known objects, 276 * the client sets the designated low order bit: 277 * 278 * mutex_enter(&container->c_objects_lock); 279 * object->o_container = (void *)((uintptr_t)object->o_container | 0x1); 280 * list_remove(&container->c_objects, object); 281 * mutex_exit(&container->c_objects_lock); 282 * 283 * In the common case, the object is freed to the magazine layer, where it may 284 * be reused on a subsequent allocation without the overhead of calling the 285 * constructor. While in the magazine it appears allocated from the point of 286 * view of the slab layer, making it a candidate for the move callback. Most 287 * objects unrecognized by the client in the move callback fall into this 288 * category and are cheaply distinguished from known objects by the test 289 * described earlier. Since recognition is cheap for the client, and searching 290 * magazines is expensive for kmem, kmem defers searching until the client first 291 * returns KMEM_CBRC_DONT_KNOW. As long as the needed effort is reasonable, kmem 292 * elsewhere does what it can to avoid bothering the client unnecessarily. 293 * 294 * Invalidating the designated pointer member before freeing the object marks 295 * the object to be avoided in the callback, and conversely, assigning a valid 296 * value to the designated pointer member after allocating the object makes the 297 * object fair game for the callback: 298 * 299 * ... allocate object ... 300 * ... set any initial state not set by the constructor ... 301 * 302 * mutex_enter(&container->c_objects_lock); 303 * list_insert_tail(&container->c_objects, object); 304 * membar_producer(); 305 * object->o_container = container; 306 * mutex_exit(&container->c_objects_lock); 307 * 308 * Note that everything else must be valid before setting o_container makes the 309 * object fair game for the move callback. The membar_producer() call ensures 310 * that all the object's state is written to memory before setting the pointer 311 * that transitions the object from state #3 or #7 (allocated, constructed, not 312 * yet in use) to state #4 (in use, valid). That's important because the move 313 * function has to check the validity of the pointer before it can safely 314 * acquire the lock protecting the collection where it expects to find known 315 * objects. 316 * 317 * This method of distinguishing known objects observes the usual symmetry: 318 * invalidating the designated pointer is the first thing the client does before 319 * freeing the object, and setting the designated pointer is the last thing the 320 * client does after allocating the object. Of course, the client is not 321 * required to use this method. Fundamentally, how the client recognizes known 322 * objects is completely up to the client, but this method is recommended as an 323 * efficient and safe way to take advantage of the guarantees made by kmem. If 324 * the entire object is arbitrary data without any markable bits from a suitable 325 * pointer member, then the client must find some other method, such as 326 * searching a hash table of known objects. 327 * 328 * 2.5 Preventing Objects From Moving 329 * 330 * Besides a way to distinguish known objects, the other thing that the client 331 * needs is a strategy to ensure that an object will not move while the client 332 * is actively using it. The details of satisfying this requirement tend to be 333 * highly cache-specific. It might seem that the same rules that let a client 334 * remove an object safely should also decide when an object can be moved 335 * safely. However, any object state that makes a removal attempt invalid is 336 * likely to be long-lasting for objects that the client does not expect to 337 * remove. kmem knows nothing about the object state and is equally likely (from 338 * the client's point of view) to request a move for any object in the cache, 339 * whether prepared for removal or not. Even a low percentage of objects stuck 340 * in place by unremovability will defeat the consolidator if the stuck objects 341 * are the same long-lived allocations likely to hold slabs hostage. 342 * Fundamentally, the consolidator is not aimed at common cases. Severe external 343 * fragmentation is a worst case scenario manifested as sparsely allocated 344 * slabs, by definition a low percentage of the cache's objects. When deciding 345 * what makes an object movable, keep in mind the goal of the consolidator: to 346 * bring worst-case external fragmentation within the limits guaranteed for 347 * internal fragmentation. Removability is a poor criterion if it is likely to 348 * exclude more than an insignificant percentage of objects for long periods of 349 * time. 350 * 351 * A tricky general solution exists, and it has the advantage of letting you 352 * move any object at almost any moment, practically eliminating the likelihood 353 * that an object can hold a slab hostage. However, if there is a cache-specific 354 * way to ensure that an object is not actively in use in the vast majority of 355 * cases, a simpler solution that leverages this cache-specific knowledge is 356 * preferred. 357 * 358 * 2.5.1 Cache-Specific Solution 359 * 360 * As an example of a cache-specific solution, the ZFS znode cache takes 361 * advantage of the fact that the vast majority of znodes are only being 362 * referenced from the DNLC. (A typical case might be a few hundred in active 363 * use and a hundred thousand in the DNLC.) In the move callback, after the ZFS 364 * client has established that it recognizes the znode and can access its fields 365 * safely (using the method described earlier), it then tests whether the znode 366 * is referenced by anything other than the DNLC. If so, it assumes that the 367 * znode may be in active use and is unsafe to move, so it drops its locks and 368 * returns KMEM_CBRC_LATER. The advantage of this strategy is that everywhere 369 * else znodes are used, no change is needed to protect against the possibility 370 * of the znode moving. The disadvantage is that it remains possible for an 371 * application to hold a znode slab hostage with an open file descriptor. 372 * However, this case ought to be rare and the consolidator has a way to deal 373 * with it: If the client responds KMEM_CBRC_LATER repeatedly for the same 374 * object, kmem eventually stops believing it and treats the slab as if the 375 * client had responded KMEM_CBRC_NO. Having marked the hostage slab, kmem can 376 * then focus on getting it off of the partial slab list by allocating rather 377 * than freeing all of its objects. (Either way of getting a slab off the 378 * free list reduces fragmentation.) 379 * 380 * 2.5.2 General Solution 381 * 382 * The general solution, on the other hand, requires an explicit hold everywhere 383 * the object is used to prevent it from moving. To keep the client locking 384 * strategy as uncomplicated as possible, kmem guarantees the simplifying 385 * assumption that move callbacks are sequential, even across multiple caches. 386 * Internally, a global queue processed by a single thread supports all caches 387 * implementing the callback function. No matter how many caches supply a move 388 * function, the consolidator never moves more than one object at a time, so the 389 * client does not have to worry about tricky lock ordering involving several 390 * related objects from different kmem caches. 391 * 392 * The general solution implements the explicit hold as a read-write lock, which 393 * allows multiple readers to access an object from the cache simultaneously 394 * while a single writer is excluded from moving it. A single rwlock for the 395 * entire cache would lock out all threads from using any of the cache's objects 396 * even though only a single object is being moved, so to reduce contention, 397 * the client can fan out the single rwlock into an array of rwlocks hashed by 398 * the object address, making it probable that moving one object will not 399 * prevent other threads from using a different object. The rwlock cannot be a 400 * member of the object itself, because the possibility of the object moving 401 * makes it unsafe to access any of the object's fields until the lock is 402 * acquired. 403 * 404 * Assuming a small, fixed number of locks, it's possible that multiple objects 405 * will hash to the same lock. A thread that needs to use multiple objects in 406 * the same function may acquire the same lock multiple times. Since rwlocks are 407 * reentrant for readers, and since there is never more than a single writer at 408 * a time (assuming that the client acquires the lock as a writer only when 409 * moving an object inside the callback), there would seem to be no problem. 410 * However, a client locking multiple objects in the same function must handle 411 * one case of potential deadlock: Assume that thread A needs to prevent both 412 * object 1 and object 2 from moving, and thread B, the callback, meanwhile 413 * tries to move object 3. It's possible, if objects 1, 2, and 3 all hash to the 414 * same lock, that thread A will acquire the lock for object 1 as a reader 415 * before thread B sets the lock's write-wanted bit, preventing thread A from 416 * reacquiring the lock for object 2 as a reader. Unable to make forward 417 * progress, thread A will never release the lock for object 1, resulting in 418 * deadlock. 419 * 420 * There are two ways of avoiding the deadlock just described. The first is to 421 * use rw_tryenter() rather than rw_enter() in the callback function when 422 * attempting to acquire the lock as a writer. If tryenter discovers that the 423 * same object (or another object hashed to the same lock) is already in use, it 424 * aborts the callback and returns KMEM_CBRC_LATER. The second way is to use 425 * rprwlock_t (declared in common/fs/zfs/sys/rprwlock.h) instead of rwlock_t, 426 * since it allows a thread to acquire the lock as a reader in spite of a 427 * waiting writer. This second approach insists on moving the object now, no 428 * matter how many readers the move function must wait for in order to do so, 429 * and could delay the completion of the callback indefinitely (blocking 430 * callbacks to other clients). In practice, a less insistent callback using 431 * rw_tryenter() returns KMEM_CBRC_LATER infrequently enough that there seems 432 * little reason to use anything else. 433 * 434 * Avoiding deadlock is not the only problem that an implementation using an 435 * explicit hold needs to solve. Locking the object in the first place (to 436 * prevent it from moving) remains a problem, since the object could move 437 * between the time you obtain a pointer to the object and the time you acquire 438 * the rwlock hashed to that pointer value. Therefore the client needs to 439 * recheck the value of the pointer after acquiring the lock, drop the lock if 440 * the value has changed, and try again. This requires a level of indirection: 441 * something that points to the object rather than the object itself, that the 442 * client can access safely while attempting to acquire the lock. (The object 443 * itself cannot be referenced safely because it can move at any time.) 444 * The following lock-acquisition function takes whatever is safe to reference 445 * (arg), follows its pointer to the object (using function f), and tries as 446 * often as necessary to acquire the hashed lock and verify that the object 447 * still has not moved: 448 * 449 * object_t * 450 * object_hold(object_f f, void *arg) 451 * { 452 * object_t *op; 453 * 454 * op = f(arg); 455 * if (op == NULL) { 456 * return (NULL); 457 * } 458 * 459 * rw_enter(OBJECT_RWLOCK(op), RW_READER); 460 * while (op != f(arg)) { 461 * rw_exit(OBJECT_RWLOCK(op)); 462 * op = f(arg); 463 * if (op == NULL) { 464 * break; 465 * } 466 * rw_enter(OBJECT_RWLOCK(op), RW_READER); 467 * } 468 * 469 * return (op); 470 * } 471 * 472 * The OBJECT_RWLOCK macro hashes the object address to obtain the rwlock. The 473 * lock reacquisition loop, while necessary, almost never executes. The function 474 * pointer f (used to obtain the object pointer from arg) has the following type 475 * definition: 476 * 477 * typedef object_t *(*object_f)(void *arg); 478 * 479 * An object_f implementation is likely to be as simple as accessing a structure 480 * member: 481 * 482 * object_t * 483 * s_object(void *arg) 484 * { 485 * something_t *sp = arg; 486 * return (sp->s_object); 487 * } 488 * 489 * The flexibility of a function pointer allows the path to the object to be 490 * arbitrarily complex and also supports the notion that depending on where you 491 * are using the object, you may need to get it from someplace different. 492 * 493 * The function that releases the explicit hold is simpler because it does not 494 * have to worry about the object moving: 495 * 496 * void 497 * object_rele(object_t *op) 498 * { 499 * rw_exit(OBJECT_RWLOCK(op)); 500 * } 501 * 502 * The caller is spared these details so that obtaining and releasing an 503 * explicit hold feels like a simple mutex_enter()/mutex_exit() pair. The caller 504 * of object_hold() only needs to know that the returned object pointer is valid 505 * if not NULL and that the object will not move until released. 506 * 507 * Although object_hold() prevents an object from moving, it does not prevent it 508 * from being freed. The caller must take measures before calling object_hold() 509 * (afterwards is too late) to ensure that the held object cannot be freed. The 510 * caller must do so without accessing the unsafe object reference, so any lock 511 * or reference count used to ensure the continued existence of the object must 512 * live outside the object itself. 513 * 514 * Obtaining a new object is a special case where an explicit hold is impossible 515 * for the caller. Any function that returns a newly allocated object (either as 516 * a return value, or as an in-out paramter) must return it already held; after 517 * the caller gets it is too late, since the object cannot be safely accessed 518 * without the level of indirection described earlier. The following 519 * object_alloc() example uses the same code shown earlier to transition a new 520 * object into the state of being recognized (by the client) as a known object. 521 * The function must acquire the hold (rw_enter) before that state transition 522 * makes the object movable: 523 * 524 * static object_t * 525 * object_alloc(container_t *container) 526 * { 527 * object_t *object = kmem_cache_create(object_cache, 0); 528 * ... set any initial state not set by the constructor ... 529 * rw_enter(OBJECT_RWLOCK(object), RW_READER); 530 * mutex_enter(&container->c_objects_lock); 531 * list_insert_tail(&container->c_objects, object); 532 * membar_producer(); 533 * object->o_container = container; 534 * mutex_exit(&container->c_objects_lock); 535 * return (object); 536 * } 537 * 538 * Functions that implicitly acquire an object hold (any function that calls 539 * object_alloc() to supply an object for the caller) need to be carefully noted 540 * so that the matching object_rele() is not neglected. Otherwise, leaked holds 541 * prevent all objects hashed to the affected rwlocks from ever being moved. 542 * 543 * The pointer to a held object can be hashed to the holding rwlock even after 544 * the object has been freed. Although it is possible to release the hold 545 * after freeing the object, you may decide to release the hold implicitly in 546 * whatever function frees the object, so as to release the hold as soon as 547 * possible, and for the sake of symmetry with the function that implicitly 548 * acquires the hold when it allocates the object. Here, object_free() releases 549 * the hold acquired by object_alloc(). Its implicit object_rele() forms a 550 * matching pair with object_hold(): 551 * 552 * void 553 * object_free(object_t *object) 554 * { 555 * container_t *container; 556 * 557 * ASSERT(object_held(object)); 558 * container = object->o_container; 559 * mutex_enter(&container->c_objects_lock); 560 * object->o_container = 561 * (void *)((uintptr_t)object->o_container | 0x1); 562 * list_remove(&container->c_objects, object); 563 * mutex_exit(&container->c_objects_lock); 564 * object_rele(object); 565 * kmem_cache_free(object_cache, object); 566 * } 567 * 568 * Note that object_free() cannot safely accept an object pointer as an argument 569 * unless the object is already held. Any function that calls object_free() 570 * needs to be carefully noted since it similarly forms a matching pair with 571 * object_hold(). 572 * 573 * To complete the picture, the following callback function implements the 574 * general solution by moving objects only if they are currently unheld: 575 * 576 * static kmem_cbrc_t 577 * object_move(void *buf, void *newbuf, size_t size, void *arg) 578 * { 579 * object_t *op = buf, *np = newbuf; 580 * container_t *container; 581 * 582 * container = op->o_container; 583 * if ((uintptr_t)container & 0x3) { 584 * return (KMEM_CBRC_DONT_KNOW); 585 * } 586 * 587 * // Ensure that the container structure does not go away. 588 * if (container_hold(container) == 0) { 589 * return (KMEM_CBRC_DONT_KNOW); 590 * } 591 * 592 * mutex_enter(&container->c_objects_lock); 593 * if (container != op->o_container) { 594 * mutex_exit(&container->c_objects_lock); 595 * container_rele(container); 596 * return (KMEM_CBRC_DONT_KNOW); 597 * } 598 * 599 * if (rw_tryenter(OBJECT_RWLOCK(op), RW_WRITER) == 0) { 600 * mutex_exit(&container->c_objects_lock); 601 * container_rele(container); 602 * return (KMEM_CBRC_LATER); 603 * } 604 * 605 * object_move_impl(op, np); // critical section 606 * rw_exit(OBJECT_RWLOCK(op)); 607 * 608 * op->o_container = (void *)((uintptr_t)op->o_container | 0x1); 609 * list_link_replace(&op->o_link_node, &np->o_link_node); 610 * mutex_exit(&container->c_objects_lock); 611 * container_rele(container); 612 * return (KMEM_CBRC_YES); 613 * } 614 * 615 * Note that object_move() must invalidate the designated o_container pointer of 616 * the old object in the same way that object_free() does, since kmem will free 617 * the object in response to the KMEM_CBRC_YES return value. 618 * 619 * The lock order in object_move() differs from object_alloc(), which locks 620 * OBJECT_RWLOCK first and &container->c_objects_lock second, but as long as the 621 * callback uses rw_tryenter() (preventing the deadlock described earlier), it's 622 * not a problem. Holding the lock on the object list in the example above 623 * through the entire callback not only prevents the object from going away, it 624 * also allows you to lock the list elsewhere and know that none of its elements 625 * will move during iteration. 626 * 627 * Adding an explicit hold everywhere an object from the cache is used is tricky 628 * and involves much more change to client code than a cache-specific solution 629 * that leverages existing state to decide whether or not an object is 630 * movable. However, this approach has the advantage that no object remains 631 * immovable for any significant length of time, making it extremely unlikely 632 * that long-lived allocations can continue holding slabs hostage; and it works 633 * for any cache. 634 * 635 * 3. Consolidator Implementation 636 * 637 * Once the client supplies a move function that a) recognizes known objects and 638 * b) avoids moving objects that are actively in use, the remaining work is up 639 * to the consolidator to decide which objects to move and when to issue 640 * callbacks. 641 * 642 * The consolidator relies on the fact that a cache's slabs are ordered by 643 * usage. Each slab has a fixed number of objects. Depending on the slab's 644 * "color" (the offset of the first object from the beginning of the slab; 645 * offsets are staggered to mitigate false sharing of cache lines) it is either 646 * the maximum number of objects per slab determined at cache creation time or 647 * else the number closest to the maximum that fits within the space remaining 648 * after the initial offset. A completely allocated slab may contribute some 649 * internal fragmentation (per-slab overhead) but no external fragmentation, so 650 * it is of no interest to the consolidator. At the other extreme, slabs whose 651 * objects have all been freed to the slab are released to the virtual memory 652 * (VM) subsystem (objects freed to magazines are still allocated as far as the 653 * slab is concerned). External fragmentation exists when there are slabs 654 * somewhere between these extremes. A partial slab has at least one but not all 655 * of its objects allocated. The more partial slabs, and the fewer allocated 656 * objects on each of them, the higher the fragmentation. Hence the 657 * consolidator's overall strategy is to reduce the number of partial slabs by 658 * moving allocated objects from the least allocated slabs to the most allocated 659 * slabs. 660 * 661 * Partial slabs are kept in an AVL tree ordered by usage. Completely allocated 662 * slabs are kept separately in an unordered list. Since the majority of slabs 663 * tend to be completely allocated (a typical unfragmented cache may have 664 * thousands of complete slabs and only a single partial slab), separating 665 * complete slabs improves the efficiency of partial slab ordering, since the 666 * complete slabs do not affect the depth or balance of the AVL tree. This 667 * ordered sequence of partial slabs acts as a "free list" supplying objects for 668 * allocation requests. 669 * 670 * Objects are always allocated from the first partial slab in the free list, 671 * where the allocation is most likely to eliminate a partial slab (by 672 * completely allocating it). Conversely, when a single object from a completely 673 * allocated slab is freed to the slab, that slab is added to the front of the 674 * free list. Since most free list activity involves highly allocated slabs 675 * coming and going at the front of the list, slabs tend naturally toward the 676 * ideal order: highly allocated at the front, sparsely allocated at the back. 677 * Slabs with few allocated objects are likely to become completely free if they 678 * keep a safe distance away from the front of the free list. Slab misorders 679 * interfere with the natural tendency of slabs to become completely free or 680 * completely allocated. For example, a slab with a single allocated object 681 * needs only a single free to escape the cache; its natural desire is 682 * frustrated when it finds itself at the front of the list where a second 683 * allocation happens just before the free could have released it. Another slab 684 * with all but one object allocated might have supplied the buffer instead, so 685 * that both (as opposed to neither) of the slabs would have been taken off the 686 * free list. 687 * 688 * Although slabs tend naturally toward the ideal order, misorders allowed by a 689 * simple list implementation defeat the consolidator's strategy of merging 690 * least- and most-allocated slabs. Without an AVL tree to guarantee order, kmem 691 * needs another way to fix misorders to optimize its callback strategy. One 692 * approach is to periodically scan a limited number of slabs, advancing a 693 * marker to hold the current scan position, and to move extreme misorders to 694 * the front or back of the free list and to the front or back of the current 695 * scan range. By making consecutive scan ranges overlap by one slab, the least 696 * allocated slab in the current range can be carried along from the end of one 697 * scan to the start of the next. 698 * 699 * Maintaining partial slabs in an AVL tree relieves kmem of this additional 700 * task, however. Since most of the cache's activity is in the magazine layer, 701 * and allocations from the slab layer represent only a startup cost, the 702 * overhead of maintaining a balanced tree is not a significant concern compared 703 * to the opportunity of reducing complexity by eliminating the partial slab 704 * scanner just described. The overhead of an AVL tree is minimized by 705 * maintaining only partial slabs in the tree and keeping completely allocated 706 * slabs separately in a list. To avoid increasing the size of the slab 707 * structure the AVL linkage pointers are reused for the slab's list linkage, 708 * since the slab will always be either partial or complete, never stored both 709 * ways at the same time. To further minimize the overhead of the AVL tree the 710 * compare function that orders partial slabs by usage divides the range of 711 * allocated object counts into bins such that counts within the same bin are 712 * considered equal. Binning partial slabs makes it less likely that allocating 713 * or freeing a single object will change the slab's order, requiring a tree 714 * reinsertion (an avl_remove() followed by an avl_add(), both potentially 715 * requiring some rebalancing of the tree). Allocation counts closest to 716 * completely free and completely allocated are left unbinned (finely sorted) to 717 * better support the consolidator's strategy of merging slabs at either 718 * extreme. 719 * 720 * 3.1 Assessing Fragmentation and Selecting Candidate Slabs 721 * 722 * The consolidator piggybacks on the kmem maintenance thread and is called on 723 * the same interval as kmem_cache_update(), once per cache every fifteen 724 * seconds. kmem maintains a running count of unallocated objects in the slab 725 * layer (cache_bufslab). The consolidator checks whether that number exceeds 726 * 12.5% (1/8) of the total objects in the cache (cache_buftotal), and whether 727 * there is a significant number of slabs in the cache (arbitrarily a minimum 728 * 101 total slabs). Unused objects that have fallen out of the magazine layer's 729 * working set are included in the assessment, and magazines in the depot are 730 * reaped if those objects would lift cache_bufslab above the fragmentation 731 * threshold. Once the consolidator decides that a cache is fragmented, it looks 732 * for a candidate slab to reclaim, starting at the end of the partial slab free 733 * list and scanning backwards. At first the consolidator is choosy: only a slab 734 * with fewer than 12.5% (1/8) of its objects allocated qualifies (or else a 735 * single allocated object, regardless of percentage). If there is difficulty 736 * finding a candidate slab, kmem raises the allocation threshold incrementally, 737 * up to a maximum 87.5% (7/8), so that eventually the consolidator will reduce 738 * external fragmentation (unused objects on the free list) below 12.5% (1/8), 739 * even in the worst case of every slab in the cache being almost 7/8 allocated. 740 * The threshold can also be lowered incrementally when candidate slabs are easy 741 * to find, and the threshold is reset to the minimum 1/8 as soon as the cache 742 * is no longer fragmented. 743 * 744 * 3.2 Generating Callbacks 745 * 746 * Once an eligible slab is chosen, a callback is generated for every allocated 747 * object on the slab, in the hope that the client will move everything off the 748 * slab and make it reclaimable. Objects selected as move destinations are 749 * chosen from slabs at the front of the free list. Assuming slabs in the ideal 750 * order (most allocated at the front, least allocated at the back) and a 751 * cooperative client, the consolidator will succeed in removing slabs from both 752 * ends of the free list, completely allocating on the one hand and completely 753 * freeing on the other. Objects selected as move destinations are allocated in 754 * the kmem maintenance thread where move requests are enqueued. A separate 755 * callback thread removes pending callbacks from the queue and calls the 756 * client. The separate thread ensures that client code (the move function) does 757 * not interfere with internal kmem maintenance tasks. A map of pending 758 * callbacks keyed by object address (the object to be moved) is checked to 759 * ensure that duplicate callbacks are not generated for the same object. 760 * Allocating the move destination (the object to move to) prevents subsequent 761 * callbacks from selecting the same destination as an earlier pending callback. 762 * 763 * Move requests can also be generated by kmem_cache_reap() when the system is 764 * desperate for memory and by kmem_cache_move_notify(), called by the client to 765 * notify kmem that a move refused earlier with KMEM_CBRC_LATER is now possible. 766 * The map of pending callbacks is protected by the same lock that protects the 767 * slab layer. 768 * 769 * When the system is desperate for memory, kmem does not bother to determine 770 * whether or not the cache exceeds the fragmentation threshold, but tries to 771 * consolidate as many slabs as possible. Normally, the consolidator chews 772 * slowly, one sparsely allocated slab at a time during each maintenance 773 * interval that the cache is fragmented. When desperate, the consolidator 774 * starts at the last partial slab and enqueues callbacks for every allocated 775 * object on every partial slab, working backwards until it reaches the first 776 * partial slab. The first partial slab, meanwhile, advances in pace with the 777 * consolidator as allocations to supply move destinations for the enqueued 778 * callbacks use up the highly allocated slabs at the front of the free list. 779 * Ideally, the overgrown free list collapses like an accordion, starting at 780 * both ends and ending at the center with a single partial slab. 781 * 782 * 3.3 Client Responses 783 * 784 * When the client returns KMEM_CBRC_NO in response to the move callback, kmem 785 * marks the slab that supplied the stuck object non-reclaimable and moves it to 786 * front of the free list. The slab remains marked as long as it remains on the 787 * free list, and it appears more allocated to the partial slab compare function 788 * than any unmarked slab, no matter how many of its objects are allocated. 789 * Since even one immovable object ties up the entire slab, the goal is to 790 * completely allocate any slab that cannot be completely freed. kmem does not 791 * bother generating callbacks to move objects from a marked slab unless the 792 * system is desperate. 793 * 794 * When the client responds KMEM_CBRC_LATER, kmem increments a count for the 795 * slab. If the client responds LATER too many times, kmem disbelieves and 796 * treats the response as a NO. The count is cleared when the slab is taken off 797 * the partial slab list or when the client moves one of the slab's objects. 798 * 799 * 4. Observability 800 * 801 * A kmem cache's external fragmentation is best observed with 'mdb -k' using 802 * the ::kmem_slabs dcmd. For a complete description of the command, enter 803 * '::help kmem_slabs' at the mdb prompt. 804 */ 805 806 #include <sys/kmem_impl.h> 807 #include <sys/vmem_impl.h> 808 #include <sys/param.h> 809 #include <sys/sysmacros.h> 810 #include <sys/vm.h> 811 #include <sys/proc.h> 812 #include <sys/tuneable.h> 813 #include <sys/systm.h> 814 #include <sys/cmn_err.h> 815 #include <sys/debug.h> 816 #include <sys/sdt.h> 817 #include <sys/mutex.h> 818 #include <sys/bitmap.h> 819 #include <sys/atomic.h> 820 #include <sys/kobj.h> 821 #include <sys/disp.h> 822 #include <vm/seg_kmem.h> 823 #include <sys/log.h> 824 #include <sys/callb.h> 825 #include <sys/taskq.h> 826 #include <sys/modctl.h> 827 #include <sys/reboot.h> 828 #include <sys/id32.h> 829 #include <sys/zone.h> 830 #include <sys/netstack.h> 831 #ifdef DEBUG 832 #include <sys/random.h> 833 #endif 834 835 extern void streams_msg_init(void); 836 extern int segkp_fromheap; 837 extern void segkp_cache_free(void); 838 839 struct kmem_cache_kstat { 840 kstat_named_t kmc_buf_size; 841 kstat_named_t kmc_align; 842 kstat_named_t kmc_chunk_size; 843 kstat_named_t kmc_slab_size; 844 kstat_named_t kmc_alloc; 845 kstat_named_t kmc_alloc_fail; 846 kstat_named_t kmc_free; 847 kstat_named_t kmc_depot_alloc; 848 kstat_named_t kmc_depot_free; 849 kstat_named_t kmc_depot_contention; 850 kstat_named_t kmc_slab_alloc; 851 kstat_named_t kmc_slab_free; 852 kstat_named_t kmc_buf_constructed; 853 kstat_named_t kmc_buf_avail; 854 kstat_named_t kmc_buf_inuse; 855 kstat_named_t kmc_buf_total; 856 kstat_named_t kmc_buf_max; 857 kstat_named_t kmc_slab_create; 858 kstat_named_t kmc_slab_destroy; 859 kstat_named_t kmc_vmem_source; 860 kstat_named_t kmc_hash_size; 861 kstat_named_t kmc_hash_lookup_depth; 862 kstat_named_t kmc_hash_rescale; 863 kstat_named_t kmc_full_magazines; 864 kstat_named_t kmc_empty_magazines; 865 kstat_named_t kmc_magazine_size; 866 kstat_named_t kmc_move_callbacks; 867 kstat_named_t kmc_move_yes; 868 kstat_named_t kmc_move_no; 869 kstat_named_t kmc_move_later; 870 kstat_named_t kmc_move_dont_need; 871 kstat_named_t kmc_move_dont_know; 872 kstat_named_t kmc_move_hunt_found; 873 } kmem_cache_kstat = { 874 { "buf_size", KSTAT_DATA_UINT64 }, 875 { "align", KSTAT_DATA_UINT64 }, 876 { "chunk_size", KSTAT_DATA_UINT64 }, 877 { "slab_size", KSTAT_DATA_UINT64 }, 878 { "alloc", KSTAT_DATA_UINT64 }, 879 { "alloc_fail", KSTAT_DATA_UINT64 }, 880 { "free", KSTAT_DATA_UINT64 }, 881 { "depot_alloc", KSTAT_DATA_UINT64 }, 882 { "depot_free", KSTAT_DATA_UINT64 }, 883 { "depot_contention", KSTAT_DATA_UINT64 }, 884 { "slab_alloc", KSTAT_DATA_UINT64 }, 885 { "slab_free", KSTAT_DATA_UINT64 }, 886 { "buf_constructed", KSTAT_DATA_UINT64 }, 887 { "buf_avail", KSTAT_DATA_UINT64 }, 888 { "buf_inuse", KSTAT_DATA_UINT64 }, 889 { "buf_total", KSTAT_DATA_UINT64 }, 890 { "buf_max", KSTAT_DATA_UINT64 }, 891 { "slab_create", KSTAT_DATA_UINT64 }, 892 { "slab_destroy", KSTAT_DATA_UINT64 }, 893 { "vmem_source", KSTAT_DATA_UINT64 }, 894 { "hash_size", KSTAT_DATA_UINT64 }, 895 { "hash_lookup_depth", KSTAT_DATA_UINT64 }, 896 { "hash_rescale", KSTAT_DATA_UINT64 }, 897 { "full_magazines", KSTAT_DATA_UINT64 }, 898 { "empty_magazines", KSTAT_DATA_UINT64 }, 899 { "magazine_size", KSTAT_DATA_UINT64 }, 900 { "move_callbacks", KSTAT_DATA_UINT64 }, 901 { "move_yes", KSTAT_DATA_UINT64 }, 902 { "move_no", KSTAT_DATA_UINT64 }, 903 { "move_later", KSTAT_DATA_UINT64 }, 904 { "move_dont_need", KSTAT_DATA_UINT64 }, 905 { "move_dont_know", KSTAT_DATA_UINT64 }, 906 { "move_hunt_found", KSTAT_DATA_UINT64 }, 907 }; 908 909 static kmutex_t kmem_cache_kstat_lock; 910 911 /* 912 * The default set of caches to back kmem_alloc(). 913 * These sizes should be reevaluated periodically. 914 * 915 * We want allocations that are multiples of the coherency granularity 916 * (64 bytes) to be satisfied from a cache which is a multiple of 64 917 * bytes, so that it will be 64-byte aligned. For all multiples of 64, 918 * the next kmem_cache_size greater than or equal to it must be a 919 * multiple of 64. 920 */ 921 static const int kmem_alloc_sizes[] = { 922 1 * 8, 923 2 * 8, 924 3 * 8, 925 4 * 8, 5 * 8, 6 * 8, 7 * 8, 926 4 * 16, 5 * 16, 6 * 16, 7 * 16, 927 4 * 32, 5 * 32, 6 * 32, 7 * 32, 928 4 * 64, 5 * 64, 6 * 64, 7 * 64, 929 4 * 128, 5 * 128, 6 * 128, 7 * 128, 930 P2ALIGN(8192 / 7, 64), 931 P2ALIGN(8192 / 6, 64), 932 P2ALIGN(8192 / 5, 64), 933 P2ALIGN(8192 / 4, 64), 934 P2ALIGN(8192 / 3, 64), 935 P2ALIGN(8192 / 2, 64), 936 P2ALIGN(8192 / 1, 64), 937 4096 * 3, 938 8192 * 2, 939 8192 * 3, 940 8192 * 4, 941 }; 942 943 #define KMEM_MAXBUF 32768 944 945 static kmem_cache_t *kmem_alloc_table[KMEM_MAXBUF >> KMEM_ALIGN_SHIFT]; 946 947 static kmem_magtype_t kmem_magtype[] = { 948 { 1, 8, 3200, 65536 }, 949 { 3, 16, 256, 32768 }, 950 { 7, 32, 64, 16384 }, 951 { 15, 64, 0, 8192 }, 952 { 31, 64, 0, 4096 }, 953 { 47, 64, 0, 2048 }, 954 { 63, 64, 0, 1024 }, 955 { 95, 64, 0, 512 }, 956 { 143, 64, 0, 0 }, 957 }; 958 959 static uint32_t kmem_reaping; 960 static uint32_t kmem_reaping_idspace; 961 962 /* 963 * kmem tunables 964 */ 965 clock_t kmem_reap_interval; /* cache reaping rate [15 * HZ ticks] */ 966 int kmem_depot_contention = 3; /* max failed tryenters per real interval */ 967 pgcnt_t kmem_reapahead = 0; /* start reaping N pages before pageout */ 968 int kmem_panic = 1; /* whether to panic on error */ 969 int kmem_logging = 1; /* kmem_log_enter() override */ 970 uint32_t kmem_mtbf = 0; /* mean time between failures [default: off] */ 971 size_t kmem_transaction_log_size; /* transaction log size [2% of memory] */ 972 size_t kmem_content_log_size; /* content log size [2% of memory] */ 973 size_t kmem_failure_log_size; /* failure log [4 pages per CPU] */ 974 size_t kmem_slab_log_size; /* slab create log [4 pages per CPU] */ 975 size_t kmem_content_maxsave = 256; /* KMF_CONTENTS max bytes to log */ 976 size_t kmem_lite_minsize = 0; /* minimum buffer size for KMF_LITE */ 977 size_t kmem_lite_maxalign = 1024; /* maximum buffer alignment for KMF_LITE */ 978 int kmem_lite_pcs = 4; /* number of PCs to store in KMF_LITE mode */ 979 size_t kmem_maxverify; /* maximum bytes to inspect in debug routines */ 980 size_t kmem_minfirewall; /* hardware-enforced redzone threshold */ 981 982 #ifdef DEBUG 983 int kmem_flags = KMF_AUDIT | KMF_DEADBEEF | KMF_REDZONE | KMF_CONTENTS; 984 #else 985 int kmem_flags = 0; 986 #endif 987 int kmem_ready; 988 989 static kmem_cache_t *kmem_slab_cache; 990 static kmem_cache_t *kmem_bufctl_cache; 991 static kmem_cache_t *kmem_bufctl_audit_cache; 992 993 static kmutex_t kmem_cache_lock; /* inter-cache linkage only */ 994 static list_t kmem_caches; 995 996 static taskq_t *kmem_taskq; 997 static kmutex_t kmem_flags_lock; 998 static vmem_t *kmem_metadata_arena; 999 static vmem_t *kmem_msb_arena; /* arena for metadata caches */ 1000 static vmem_t *kmem_cache_arena; 1001 static vmem_t *kmem_hash_arena; 1002 static vmem_t *kmem_log_arena; 1003 static vmem_t *kmem_oversize_arena; 1004 static vmem_t *kmem_va_arena; 1005 static vmem_t *kmem_default_arena; 1006 static vmem_t *kmem_firewall_va_arena; 1007 static vmem_t *kmem_firewall_arena; 1008 1009 /* 1010 * Define KMEM_STATS to turn on statistic gathering. By default, it is only 1011 * turned on when DEBUG is also defined. 1012 */ 1013 #ifdef DEBUG 1014 #define KMEM_STATS 1015 #endif /* DEBUG */ 1016 1017 #ifdef KMEM_STATS 1018 #define KMEM_STAT_ADD(stat) ((stat)++) 1019 #define KMEM_STAT_COND_ADD(cond, stat) ((void) (!(cond) || (stat)++)) 1020 #else 1021 #define KMEM_STAT_ADD(stat) /* nothing */ 1022 #define KMEM_STAT_COND_ADD(cond, stat) /* nothing */ 1023 #endif /* KMEM_STATS */ 1024 1025 /* 1026 * kmem slab consolidator thresholds (tunables) 1027 */ 1028 static size_t kmem_frag_minslabs = 101; /* minimum total slabs */ 1029 static size_t kmem_frag_numer = 1; /* free buffers (numerator) */ 1030 static size_t kmem_frag_denom = KMEM_VOID_FRACTION; /* buffers (denominator) */ 1031 /* 1032 * Maximum number of slabs from which to move buffers during a single 1033 * maintenance interval while the system is not low on memory. 1034 */ 1035 static size_t kmem_reclaim_max_slabs = 1; 1036 /* 1037 * Number of slabs to scan backwards from the end of the partial slab list 1038 * when searching for buffers to relocate. 1039 */ 1040 static size_t kmem_reclaim_scan_range = 12; 1041 1042 #ifdef KMEM_STATS 1043 static struct { 1044 uint64_t kms_callbacks; 1045 uint64_t kms_yes; 1046 uint64_t kms_no; 1047 uint64_t kms_later; 1048 uint64_t kms_dont_need; 1049 uint64_t kms_dont_know; 1050 uint64_t kms_hunt_found_slab; 1051 uint64_t kms_hunt_found_mag; 1052 uint64_t kms_hunt_notfound; 1053 uint64_t kms_hunt_alloc_fail; 1054 uint64_t kms_hunt_lucky; 1055 uint64_t kms_notify; 1056 uint64_t kms_notify_callbacks; 1057 uint64_t kms_disbelief; 1058 uint64_t kms_already_pending; 1059 uint64_t kms_callback_alloc_fail; 1060 uint64_t kms_endscan_slab_destroyed; 1061 uint64_t kms_endscan_nomem; 1062 uint64_t kms_endscan_slab_all_used; 1063 uint64_t kms_endscan_refcnt_changed; 1064 uint64_t kms_endscan_nomove_changed; 1065 uint64_t kms_endscan_freelist; 1066 uint64_t kms_avl_update; 1067 uint64_t kms_avl_noupdate; 1068 uint64_t kms_no_longer_reclaimable; 1069 uint64_t kms_notify_no_longer_reclaimable; 1070 uint64_t kms_alloc_fail; 1071 uint64_t kms_constructor_fail; 1072 uint64_t kms_dead_slabs_freed; 1073 uint64_t kms_defrags; 1074 uint64_t kms_scan_depot_ws_reaps; 1075 uint64_t kms_debug_reaps; 1076 uint64_t kms_debug_move_scans; 1077 } kmem_move_stats; 1078 #endif /* KMEM_STATS */ 1079 1080 /* consolidator knobs */ 1081 static boolean_t kmem_move_noreap; 1082 static boolean_t kmem_move_blocked; 1083 static boolean_t kmem_move_fulltilt; 1084 static boolean_t kmem_move_any_partial; 1085 1086 #ifdef DEBUG 1087 /* 1088 * Ensure code coverage by occasionally running the consolidator even when the 1089 * caches are not fragmented (they may never be). These intervals are mean time 1090 * in cache maintenance intervals (kmem_cache_update). 1091 */ 1092 static int kmem_mtb_move = 60; /* defrag 1 slab (~15min) */ 1093 static int kmem_mtb_reap = 1800; /* defrag all slabs (~7.5hrs) */ 1094 #endif /* DEBUG */ 1095 1096 static kmem_cache_t *kmem_defrag_cache; 1097 static kmem_cache_t *kmem_move_cache; 1098 static taskq_t *kmem_move_taskq; 1099 1100 static void kmem_cache_scan(kmem_cache_t *); 1101 static void kmem_cache_defrag(kmem_cache_t *); 1102 1103 1104 kmem_log_header_t *kmem_transaction_log; 1105 kmem_log_header_t *kmem_content_log; 1106 kmem_log_header_t *kmem_failure_log; 1107 kmem_log_header_t *kmem_slab_log; 1108 1109 static int kmem_lite_count; /* # of PCs in kmem_buftag_lite_t */ 1110 1111 #define KMEM_BUFTAG_LITE_ENTER(bt, count, caller) \ 1112 if ((count) > 0) { \ 1113 pc_t *_s = ((kmem_buftag_lite_t *)(bt))->bt_history; \ 1114 pc_t *_e; \ 1115 /* memmove() the old entries down one notch */ \ 1116 for (_e = &_s[(count) - 1]; _e > _s; _e--) \ 1117 *_e = *(_e - 1); \ 1118 *_s = (uintptr_t)(caller); \ 1119 } 1120 1121 #define KMERR_MODIFIED 0 /* buffer modified while on freelist */ 1122 #define KMERR_REDZONE 1 /* redzone violation (write past end of buf) */ 1123 #define KMERR_DUPFREE 2 /* freed a buffer twice */ 1124 #define KMERR_BADADDR 3 /* freed a bad (unallocated) address */ 1125 #define KMERR_BADBUFTAG 4 /* buftag corrupted */ 1126 #define KMERR_BADBUFCTL 5 /* bufctl corrupted */ 1127 #define KMERR_BADCACHE 6 /* freed a buffer to the wrong cache */ 1128 #define KMERR_BADSIZE 7 /* alloc size != free size */ 1129 #define KMERR_BADBASE 8 /* buffer base address wrong */ 1130 1131 struct { 1132 hrtime_t kmp_timestamp; /* timestamp of panic */ 1133 int kmp_error; /* type of kmem error */ 1134 void *kmp_buffer; /* buffer that induced panic */ 1135 void *kmp_realbuf; /* real start address for buffer */ 1136 kmem_cache_t *kmp_cache; /* buffer's cache according to client */ 1137 kmem_cache_t *kmp_realcache; /* actual cache containing buffer */ 1138 kmem_slab_t *kmp_slab; /* slab accoring to kmem_findslab() */ 1139 kmem_bufctl_t *kmp_bufctl; /* bufctl */ 1140 } kmem_panic_info; 1141 1142 1143 static void 1144 copy_pattern(uint64_t pattern, void *buf_arg, size_t size) 1145 { 1146 uint64_t *bufend = (uint64_t *)((char *)buf_arg + size); 1147 uint64_t *buf = buf_arg; 1148 1149 while (buf < bufend) 1150 *buf++ = pattern; 1151 } 1152 1153 static void * 1154 verify_pattern(uint64_t pattern, void *buf_arg, size_t size) 1155 { 1156 uint64_t *bufend = (uint64_t *)((char *)buf_arg + size); 1157 uint64_t *buf; 1158 1159 for (buf = buf_arg; buf < bufend; buf++) 1160 if (*buf != pattern) 1161 return (buf); 1162 return (NULL); 1163 } 1164 1165 static void * 1166 verify_and_copy_pattern(uint64_t old, uint64_t new, void *buf_arg, size_t size) 1167 { 1168 uint64_t *bufend = (uint64_t *)((char *)buf_arg + size); 1169 uint64_t *buf; 1170 1171 for (buf = buf_arg; buf < bufend; buf++) { 1172 if (*buf != old) { 1173 copy_pattern(old, buf_arg, 1174 (char *)buf - (char *)buf_arg); 1175 return (buf); 1176 } 1177 *buf = new; 1178 } 1179 1180 return (NULL); 1181 } 1182 1183 static void 1184 kmem_cache_applyall(void (*func)(kmem_cache_t *), taskq_t *tq, int tqflag) 1185 { 1186 kmem_cache_t *cp; 1187 1188 mutex_enter(&kmem_cache_lock); 1189 for (cp = list_head(&kmem_caches); cp != NULL; 1190 cp = list_next(&kmem_caches, cp)) 1191 if (tq != NULL) 1192 (void) taskq_dispatch(tq, (task_func_t *)func, cp, 1193 tqflag); 1194 else 1195 func(cp); 1196 mutex_exit(&kmem_cache_lock); 1197 } 1198 1199 static void 1200 kmem_cache_applyall_id(void (*func)(kmem_cache_t *), taskq_t *tq, int tqflag) 1201 { 1202 kmem_cache_t *cp; 1203 1204 mutex_enter(&kmem_cache_lock); 1205 for (cp = list_head(&kmem_caches); cp != NULL; 1206 cp = list_next(&kmem_caches, cp)) { 1207 if (!(cp->cache_cflags & KMC_IDENTIFIER)) 1208 continue; 1209 if (tq != NULL) 1210 (void) taskq_dispatch(tq, (task_func_t *)func, cp, 1211 tqflag); 1212 else 1213 func(cp); 1214 } 1215 mutex_exit(&kmem_cache_lock); 1216 } 1217 1218 /* 1219 * Debugging support. Given a buffer address, find its slab. 1220 */ 1221 static kmem_slab_t * 1222 kmem_findslab(kmem_cache_t *cp, void *buf) 1223 { 1224 kmem_slab_t *sp; 1225 1226 mutex_enter(&cp->cache_lock); 1227 for (sp = list_head(&cp->cache_complete_slabs); sp != NULL; 1228 sp = list_next(&cp->cache_complete_slabs, sp)) { 1229 if (KMEM_SLAB_MEMBER(sp, buf)) { 1230 mutex_exit(&cp->cache_lock); 1231 return (sp); 1232 } 1233 } 1234 for (sp = avl_first(&cp->cache_partial_slabs); sp != NULL; 1235 sp = AVL_NEXT(&cp->cache_partial_slabs, sp)) { 1236 if (KMEM_SLAB_MEMBER(sp, buf)) { 1237 mutex_exit(&cp->cache_lock); 1238 return (sp); 1239 } 1240 } 1241 mutex_exit(&cp->cache_lock); 1242 1243 return (NULL); 1244 } 1245 1246 static void 1247 kmem_error(int error, kmem_cache_t *cparg, void *bufarg) 1248 { 1249 kmem_buftag_t *btp = NULL; 1250 kmem_bufctl_t *bcp = NULL; 1251 kmem_cache_t *cp = cparg; 1252 kmem_slab_t *sp; 1253 uint64_t *off; 1254 void *buf = bufarg; 1255 1256 kmem_logging = 0; /* stop logging when a bad thing happens */ 1257 1258 kmem_panic_info.kmp_timestamp = gethrtime(); 1259 1260 sp = kmem_findslab(cp, buf); 1261 if (sp == NULL) { 1262 for (cp = list_tail(&kmem_caches); cp != NULL; 1263 cp = list_prev(&kmem_caches, cp)) { 1264 if ((sp = kmem_findslab(cp, buf)) != NULL) 1265 break; 1266 } 1267 } 1268 1269 if (sp == NULL) { 1270 cp = NULL; 1271 error = KMERR_BADADDR; 1272 } else { 1273 if (cp != cparg) 1274 error = KMERR_BADCACHE; 1275 else 1276 buf = (char *)bufarg - ((uintptr_t)bufarg - 1277 (uintptr_t)sp->slab_base) % cp->cache_chunksize; 1278 if (buf != bufarg) 1279 error = KMERR_BADBASE; 1280 if (cp->cache_flags & KMF_BUFTAG) 1281 btp = KMEM_BUFTAG(cp, buf); 1282 if (cp->cache_flags & KMF_HASH) { 1283 mutex_enter(&cp->cache_lock); 1284 for (bcp = *KMEM_HASH(cp, buf); bcp; bcp = bcp->bc_next) 1285 if (bcp->bc_addr == buf) 1286 break; 1287 mutex_exit(&cp->cache_lock); 1288 if (bcp == NULL && btp != NULL) 1289 bcp = btp->bt_bufctl; 1290 if (kmem_findslab(cp->cache_bufctl_cache, bcp) == 1291 NULL || P2PHASE((uintptr_t)bcp, KMEM_ALIGN) || 1292 bcp->bc_addr != buf) { 1293 error = KMERR_BADBUFCTL; 1294 bcp = NULL; 1295 } 1296 } 1297 } 1298 1299 kmem_panic_info.kmp_error = error; 1300 kmem_panic_info.kmp_buffer = bufarg; 1301 kmem_panic_info.kmp_realbuf = buf; 1302 kmem_panic_info.kmp_cache = cparg; 1303 kmem_panic_info.kmp_realcache = cp; 1304 kmem_panic_info.kmp_slab = sp; 1305 kmem_panic_info.kmp_bufctl = bcp; 1306 1307 printf("kernel memory allocator: "); 1308 1309 switch (error) { 1310 1311 case KMERR_MODIFIED: 1312 printf("buffer modified after being freed\n"); 1313 off = verify_pattern(KMEM_FREE_PATTERN, buf, cp->cache_verify); 1314 if (off == NULL) /* shouldn't happen */ 1315 off = buf; 1316 printf("modification occurred at offset 0x%lx " 1317 "(0x%llx replaced by 0x%llx)\n", 1318 (uintptr_t)off - (uintptr_t)buf, 1319 (longlong_t)KMEM_FREE_PATTERN, (longlong_t)*off); 1320 break; 1321 1322 case KMERR_REDZONE: 1323 printf("redzone violation: write past end of buffer\n"); 1324 break; 1325 1326 case KMERR_BADADDR: 1327 printf("invalid free: buffer not in cache\n"); 1328 break; 1329 1330 case KMERR_DUPFREE: 1331 printf("duplicate free: buffer freed twice\n"); 1332 break; 1333 1334 case KMERR_BADBUFTAG: 1335 printf("boundary tag corrupted\n"); 1336 printf("bcp ^ bxstat = %lx, should be %lx\n", 1337 (intptr_t)btp->bt_bufctl ^ btp->bt_bxstat, 1338 KMEM_BUFTAG_FREE); 1339 break; 1340 1341 case KMERR_BADBUFCTL: 1342 printf("bufctl corrupted\n"); 1343 break; 1344 1345 case KMERR_BADCACHE: 1346 printf("buffer freed to wrong cache\n"); 1347 printf("buffer was allocated from %s,\n", cp->cache_name); 1348 printf("caller attempting free to %s.\n", cparg->cache_name); 1349 break; 1350 1351 case KMERR_BADSIZE: 1352 printf("bad free: free size (%u) != alloc size (%u)\n", 1353 KMEM_SIZE_DECODE(((uint32_t *)btp)[0]), 1354 KMEM_SIZE_DECODE(((uint32_t *)btp)[1])); 1355 break; 1356 1357 case KMERR_BADBASE: 1358 printf("bad free: free address (%p) != alloc address (%p)\n", 1359 bufarg, buf); 1360 break; 1361 } 1362 1363 printf("buffer=%p bufctl=%p cache: %s\n", 1364 bufarg, (void *)bcp, cparg->cache_name); 1365 1366 if (bcp != NULL && (cp->cache_flags & KMF_AUDIT) && 1367 error != KMERR_BADBUFCTL) { 1368 int d; 1369 timestruc_t ts; 1370 kmem_bufctl_audit_t *bcap = (kmem_bufctl_audit_t *)bcp; 1371 1372 hrt2ts(kmem_panic_info.kmp_timestamp - bcap->bc_timestamp, &ts); 1373 printf("previous transaction on buffer %p:\n", buf); 1374 printf("thread=%p time=T-%ld.%09ld slab=%p cache: %s\n", 1375 (void *)bcap->bc_thread, ts.tv_sec, ts.tv_nsec, 1376 (void *)sp, cp->cache_name); 1377 for (d = 0; d < MIN(bcap->bc_depth, KMEM_STACK_DEPTH); d++) { 1378 ulong_t off; 1379 char *sym = kobj_getsymname(bcap->bc_stack[d], &off); 1380 printf("%s+%lx\n", sym ? sym : "?", off); 1381 } 1382 } 1383 if (kmem_panic > 0) 1384 panic("kernel heap corruption detected"); 1385 if (kmem_panic == 0) 1386 debug_enter(NULL); 1387 kmem_logging = 1; /* resume logging */ 1388 } 1389 1390 static kmem_log_header_t * 1391 kmem_log_init(size_t logsize) 1392 { 1393 kmem_log_header_t *lhp; 1394 int nchunks = 4 * max_ncpus; 1395 size_t lhsize = (size_t)&((kmem_log_header_t *)0)->lh_cpu[max_ncpus]; 1396 int i; 1397 1398 /* 1399 * Make sure that lhp->lh_cpu[] is nicely aligned 1400 * to prevent false sharing of cache lines. 1401 */ 1402 lhsize = P2ROUNDUP(lhsize, KMEM_ALIGN); 1403 lhp = vmem_xalloc(kmem_log_arena, lhsize, 64, P2NPHASE(lhsize, 64), 0, 1404 NULL, NULL, VM_SLEEP); 1405 bzero(lhp, lhsize); 1406 1407 mutex_init(&lhp->lh_lock, NULL, MUTEX_DEFAULT, NULL); 1408 lhp->lh_nchunks = nchunks; 1409 lhp->lh_chunksize = P2ROUNDUP(logsize / nchunks + 1, PAGESIZE); 1410 lhp->lh_base = vmem_alloc(kmem_log_arena, 1411 lhp->lh_chunksize * nchunks, VM_SLEEP); 1412 lhp->lh_free = vmem_alloc(kmem_log_arena, 1413 nchunks * sizeof (int), VM_SLEEP); 1414 bzero(lhp->lh_base, lhp->lh_chunksize * nchunks); 1415 1416 for (i = 0; i < max_ncpus; i++) { 1417 kmem_cpu_log_header_t *clhp = &lhp->lh_cpu[i]; 1418 mutex_init(&clhp->clh_lock, NULL, MUTEX_DEFAULT, NULL); 1419 clhp->clh_chunk = i; 1420 } 1421 1422 for (i = max_ncpus; i < nchunks; i++) 1423 lhp->lh_free[i] = i; 1424 1425 lhp->lh_head = max_ncpus; 1426 lhp->lh_tail = 0; 1427 1428 return (lhp); 1429 } 1430 1431 static void * 1432 kmem_log_enter(kmem_log_header_t *lhp, void *data, size_t size) 1433 { 1434 void *logspace; 1435 kmem_cpu_log_header_t *clhp = &lhp->lh_cpu[CPU->cpu_seqid]; 1436 1437 if (lhp == NULL || kmem_logging == 0 || panicstr) 1438 return (NULL); 1439 1440 mutex_enter(&clhp->clh_lock); 1441 clhp->clh_hits++; 1442 if (size > clhp->clh_avail) { 1443 mutex_enter(&lhp->lh_lock); 1444 lhp->lh_hits++; 1445 lhp->lh_free[lhp->lh_tail] = clhp->clh_chunk; 1446 lhp->lh_tail = (lhp->lh_tail + 1) % lhp->lh_nchunks; 1447 clhp->clh_chunk = lhp->lh_free[lhp->lh_head]; 1448 lhp->lh_head = (lhp->lh_head + 1) % lhp->lh_nchunks; 1449 clhp->clh_current = lhp->lh_base + 1450 clhp->clh_chunk * lhp->lh_chunksize; 1451 clhp->clh_avail = lhp->lh_chunksize; 1452 if (size > lhp->lh_chunksize) 1453 size = lhp->lh_chunksize; 1454 mutex_exit(&lhp->lh_lock); 1455 } 1456 logspace = clhp->clh_current; 1457 clhp->clh_current += size; 1458 clhp->clh_avail -= size; 1459 bcopy(data, logspace, size); 1460 mutex_exit(&clhp->clh_lock); 1461 return (logspace); 1462 } 1463 1464 #define KMEM_AUDIT(lp, cp, bcp) \ 1465 { \ 1466 kmem_bufctl_audit_t *_bcp = (kmem_bufctl_audit_t *)(bcp); \ 1467 _bcp->bc_timestamp = gethrtime(); \ 1468 _bcp->bc_thread = curthread; \ 1469 _bcp->bc_depth = getpcstack(_bcp->bc_stack, KMEM_STACK_DEPTH); \ 1470 _bcp->bc_lastlog = kmem_log_enter((lp), _bcp, sizeof (*_bcp)); \ 1471 } 1472 1473 static void 1474 kmem_log_event(kmem_log_header_t *lp, kmem_cache_t *cp, 1475 kmem_slab_t *sp, void *addr) 1476 { 1477 kmem_bufctl_audit_t bca; 1478 1479 bzero(&bca, sizeof (kmem_bufctl_audit_t)); 1480 bca.bc_addr = addr; 1481 bca.bc_slab = sp; 1482 bca.bc_cache = cp; 1483 KMEM_AUDIT(lp, cp, &bca); 1484 } 1485 1486 /* 1487 * Create a new slab for cache cp. 1488 */ 1489 static kmem_slab_t * 1490 kmem_slab_create(kmem_cache_t *cp, int kmflag) 1491 { 1492 size_t slabsize = cp->cache_slabsize; 1493 size_t chunksize = cp->cache_chunksize; 1494 int cache_flags = cp->cache_flags; 1495 size_t color, chunks; 1496 char *buf, *slab; 1497 kmem_slab_t *sp; 1498 kmem_bufctl_t *bcp; 1499 vmem_t *vmp = cp->cache_arena; 1500 1501 ASSERT(MUTEX_NOT_HELD(&cp->cache_lock)); 1502 1503 color = cp->cache_color + cp->cache_align; 1504 if (color > cp->cache_maxcolor) 1505 color = cp->cache_mincolor; 1506 cp->cache_color = color; 1507 1508 slab = vmem_alloc(vmp, slabsize, kmflag & KM_VMFLAGS); 1509 1510 if (slab == NULL) 1511 goto vmem_alloc_failure; 1512 1513 ASSERT(P2PHASE((uintptr_t)slab, vmp->vm_quantum) == 0); 1514 1515 /* 1516 * Reverify what was already checked in kmem_cache_set_move(), since the 1517 * consolidator depends (for correctness) on slabs being initialized 1518 * with the 0xbaddcafe memory pattern (setting a low order bit usable by 1519 * clients to distinguish uninitialized memory from known objects). 1520 */ 1521 ASSERT((cp->cache_move == NULL) || !(cp->cache_cflags & KMC_NOTOUCH)); 1522 if (!(cp->cache_cflags & KMC_NOTOUCH)) 1523 copy_pattern(KMEM_UNINITIALIZED_PATTERN, slab, slabsize); 1524 1525 if (cache_flags & KMF_HASH) { 1526 if ((sp = kmem_cache_alloc(kmem_slab_cache, kmflag)) == NULL) 1527 goto slab_alloc_failure; 1528 chunks = (slabsize - color) / chunksize; 1529 } else { 1530 sp = KMEM_SLAB(cp, slab); 1531 chunks = (slabsize - sizeof (kmem_slab_t) - color) / chunksize; 1532 } 1533 1534 sp->slab_cache = cp; 1535 sp->slab_head = NULL; 1536 sp->slab_refcnt = 0; 1537 sp->slab_base = buf = slab + color; 1538 sp->slab_chunks = chunks; 1539 sp->slab_stuck_offset = (uint32_t)-1; 1540 sp->slab_later_count = 0; 1541 sp->slab_flags = 0; 1542 1543 ASSERT(chunks > 0); 1544 while (chunks-- != 0) { 1545 if (cache_flags & KMF_HASH) { 1546 bcp = kmem_cache_alloc(cp->cache_bufctl_cache, kmflag); 1547 if (bcp == NULL) 1548 goto bufctl_alloc_failure; 1549 if (cache_flags & KMF_AUDIT) { 1550 kmem_bufctl_audit_t *bcap = 1551 (kmem_bufctl_audit_t *)bcp; 1552 bzero(bcap, sizeof (kmem_bufctl_audit_t)); 1553 bcap->bc_cache = cp; 1554 } 1555 bcp->bc_addr = buf; 1556 bcp->bc_slab = sp; 1557 } else { 1558 bcp = KMEM_BUFCTL(cp, buf); 1559 } 1560 if (cache_flags & KMF_BUFTAG) { 1561 kmem_buftag_t *btp = KMEM_BUFTAG(cp, buf); 1562 btp->bt_redzone = KMEM_REDZONE_PATTERN; 1563 btp->bt_bufctl = bcp; 1564 btp->bt_bxstat = (intptr_t)bcp ^ KMEM_BUFTAG_FREE; 1565 if (cache_flags & KMF_DEADBEEF) { 1566 copy_pattern(KMEM_FREE_PATTERN, buf, 1567 cp->cache_verify); 1568 } 1569 } 1570 bcp->bc_next = sp->slab_head; 1571 sp->slab_head = bcp; 1572 buf += chunksize; 1573 } 1574 1575 kmem_log_event(kmem_slab_log, cp, sp, slab); 1576 1577 return (sp); 1578 1579 bufctl_alloc_failure: 1580 1581 while ((bcp = sp->slab_head) != NULL) { 1582 sp->slab_head = bcp->bc_next; 1583 kmem_cache_free(cp->cache_bufctl_cache, bcp); 1584 } 1585 kmem_cache_free(kmem_slab_cache, sp); 1586 1587 slab_alloc_failure: 1588 1589 vmem_free(vmp, slab, slabsize); 1590 1591 vmem_alloc_failure: 1592 1593 kmem_log_event(kmem_failure_log, cp, NULL, NULL); 1594 atomic_add_64(&cp->cache_alloc_fail, 1); 1595 1596 return (NULL); 1597 } 1598 1599 /* 1600 * Destroy a slab. 1601 */ 1602 static void 1603 kmem_slab_destroy(kmem_cache_t *cp, kmem_slab_t *sp) 1604 { 1605 vmem_t *vmp = cp->cache_arena; 1606 void *slab = (void *)P2ALIGN((uintptr_t)sp->slab_base, vmp->vm_quantum); 1607 1608 ASSERT(MUTEX_NOT_HELD(&cp->cache_lock)); 1609 ASSERT(sp->slab_refcnt == 0); 1610 1611 if (cp->cache_flags & KMF_HASH) { 1612 kmem_bufctl_t *bcp; 1613 while ((bcp = sp->slab_head) != NULL) { 1614 sp->slab_head = bcp->bc_next; 1615 kmem_cache_free(cp->cache_bufctl_cache, bcp); 1616 } 1617 kmem_cache_free(kmem_slab_cache, sp); 1618 } 1619 vmem_free(vmp, slab, cp->cache_slabsize); 1620 } 1621 1622 static void * 1623 kmem_slab_alloc_impl(kmem_cache_t *cp, kmem_slab_t *sp) 1624 { 1625 kmem_bufctl_t *bcp, **hash_bucket; 1626 void *buf; 1627 1628 ASSERT(MUTEX_HELD(&cp->cache_lock)); 1629 /* 1630 * kmem_slab_alloc() drops cache_lock when it creates a new slab, so we 1631 * can't ASSERT(avl_is_empty(&cp->cache_partial_slabs)) here when the 1632 * slab is newly created (sp->slab_refcnt == 0). 1633 */ 1634 ASSERT((sp->slab_refcnt == 0) || (KMEM_SLAB_IS_PARTIAL(sp) && 1635 (sp == avl_first(&cp->cache_partial_slabs)))); 1636 ASSERT(sp->slab_cache == cp); 1637 1638 cp->cache_slab_alloc++; 1639 cp->cache_bufslab--; 1640 sp->slab_refcnt++; 1641 1642 bcp = sp->slab_head; 1643 if ((sp->slab_head = bcp->bc_next) == NULL) { 1644 ASSERT(KMEM_SLAB_IS_ALL_USED(sp)); 1645 if (sp->slab_refcnt == 1) { 1646 ASSERT(sp->slab_chunks == 1); 1647 } else { 1648 ASSERT(sp->slab_chunks > 1); /* the slab was partial */ 1649 avl_remove(&cp->cache_partial_slabs, sp); 1650 sp->slab_later_count = 0; /* clear history */ 1651 sp->slab_flags &= ~KMEM_SLAB_NOMOVE; 1652 sp->slab_stuck_offset = (uint32_t)-1; 1653 } 1654 list_insert_head(&cp->cache_complete_slabs, sp); 1655 cp->cache_complete_slab_count++; 1656 } else { 1657 ASSERT(KMEM_SLAB_IS_PARTIAL(sp)); 1658 if (sp->slab_refcnt == 1) { 1659 avl_add(&cp->cache_partial_slabs, sp); 1660 } else { 1661 /* 1662 * The slab is now more allocated than it was, so the 1663 * order remains unchanged. 1664 */ 1665 ASSERT(!avl_update(&cp->cache_partial_slabs, sp)); 1666 } 1667 } 1668 1669 if (cp->cache_flags & KMF_HASH) { 1670 /* 1671 * Add buffer to allocated-address hash table. 1672 */ 1673 buf = bcp->bc_addr; 1674 hash_bucket = KMEM_HASH(cp, buf); 1675 bcp->bc_next = *hash_bucket; 1676 *hash_bucket = bcp; 1677 if ((cp->cache_flags & (KMF_AUDIT | KMF_BUFTAG)) == KMF_AUDIT) { 1678 KMEM_AUDIT(kmem_transaction_log, cp, bcp); 1679 } 1680 } else { 1681 buf = KMEM_BUF(cp, bcp); 1682 } 1683 1684 ASSERT(KMEM_SLAB_MEMBER(sp, buf)); 1685 return (buf); 1686 } 1687 1688 /* 1689 * Allocate a raw (unconstructed) buffer from cp's slab layer. 1690 */ 1691 static void * 1692 kmem_slab_alloc(kmem_cache_t *cp, int kmflag) 1693 { 1694 kmem_slab_t *sp; 1695 void *buf; 1696 1697 mutex_enter(&cp->cache_lock); 1698 sp = avl_first(&cp->cache_partial_slabs); 1699 if (sp == NULL) { 1700 ASSERT(cp->cache_bufslab == 0); 1701 1702 /* 1703 * The freelist is empty. Create a new slab. 1704 */ 1705 mutex_exit(&cp->cache_lock); 1706 if ((sp = kmem_slab_create(cp, kmflag)) == NULL) { 1707 return (NULL); 1708 } 1709 mutex_enter(&cp->cache_lock); 1710 cp->cache_slab_create++; 1711 if ((cp->cache_buftotal += sp->slab_chunks) > cp->cache_bufmax) 1712 cp->cache_bufmax = cp->cache_buftotal; 1713 cp->cache_bufslab += sp->slab_chunks; 1714 } 1715 1716 buf = kmem_slab_alloc_impl(cp, sp); 1717 ASSERT((cp->cache_slab_create - cp->cache_slab_destroy) == 1718 (cp->cache_complete_slab_count + 1719 avl_numnodes(&cp->cache_partial_slabs) + 1720 (cp->cache_defrag == NULL ? 0 : cp->cache_defrag->kmd_deadcount))); 1721 mutex_exit(&cp->cache_lock); 1722 1723 return (buf); 1724 } 1725 1726 static void kmem_slab_move_yes(kmem_cache_t *, kmem_slab_t *, void *); 1727 1728 /* 1729 * Free a raw (unconstructed) buffer to cp's slab layer. 1730 */ 1731 static void 1732 kmem_slab_free(kmem_cache_t *cp, void *buf) 1733 { 1734 kmem_slab_t *sp; 1735 kmem_bufctl_t *bcp, **prev_bcpp; 1736 1737 ASSERT(buf != NULL); 1738 1739 mutex_enter(&cp->cache_lock); 1740 cp->cache_slab_free++; 1741 1742 if (cp->cache_flags & KMF_HASH) { 1743 /* 1744 * Look up buffer in allocated-address hash table. 1745 */ 1746 prev_bcpp = KMEM_HASH(cp, buf); 1747 while ((bcp = *prev_bcpp) != NULL) { 1748 if (bcp->bc_addr == buf) { 1749 *prev_bcpp = bcp->bc_next; 1750 sp = bcp->bc_slab; 1751 break; 1752 } 1753 cp->cache_lookup_depth++; 1754 prev_bcpp = &bcp->bc_next; 1755 } 1756 } else { 1757 bcp = KMEM_BUFCTL(cp, buf); 1758 sp = KMEM_SLAB(cp, buf); 1759 } 1760 1761 if (bcp == NULL || sp->slab_cache != cp || !KMEM_SLAB_MEMBER(sp, buf)) { 1762 mutex_exit(&cp->cache_lock); 1763 kmem_error(KMERR_BADADDR, cp, buf); 1764 return; 1765 } 1766 1767 if (KMEM_SLAB_OFFSET(sp, buf) == sp->slab_stuck_offset) { 1768 /* 1769 * If this is the buffer that prevented the consolidator from 1770 * clearing the slab, we can reset the slab flags now that the 1771 * buffer is freed. (It makes sense to do this in 1772 * kmem_cache_free(), where the client gives up ownership of the 1773 * buffer, but on the hot path the test is too expensive.) 1774 */ 1775 kmem_slab_move_yes(cp, sp, buf); 1776 } 1777 1778 if ((cp->cache_flags & (KMF_AUDIT | KMF_BUFTAG)) == KMF_AUDIT) { 1779 if (cp->cache_flags & KMF_CONTENTS) 1780 ((kmem_bufctl_audit_t *)bcp)->bc_contents = 1781 kmem_log_enter(kmem_content_log, buf, 1782 cp->cache_contents); 1783 KMEM_AUDIT(kmem_transaction_log, cp, bcp); 1784 } 1785 1786 bcp->bc_next = sp->slab_head; 1787 sp->slab_head = bcp; 1788 1789 cp->cache_bufslab++; 1790 ASSERT(sp->slab_refcnt >= 1); 1791 1792 if (--sp->slab_refcnt == 0) { 1793 /* 1794 * There are no outstanding allocations from this slab, 1795 * so we can reclaim the memory. 1796 */ 1797 if (sp->slab_chunks == 1) { 1798 list_remove(&cp->cache_complete_slabs, sp); 1799 cp->cache_complete_slab_count--; 1800 } else { 1801 avl_remove(&cp->cache_partial_slabs, sp); 1802 } 1803 1804 cp->cache_buftotal -= sp->slab_chunks; 1805 cp->cache_bufslab -= sp->slab_chunks; 1806 /* 1807 * Defer releasing the slab to the virtual memory subsystem 1808 * while there is a pending move callback, since we guarantee 1809 * that buffers passed to the move callback have only been 1810 * touched by kmem or by the client itself. Since the memory 1811 * patterns baddcafe (uninitialized) and deadbeef (freed) both 1812 * set at least one of the two lowest order bits, the client can 1813 * test those bits in the move callback to determine whether or 1814 * not it knows about the buffer (assuming that the client also 1815 * sets one of those low order bits whenever it frees a buffer). 1816 */ 1817 if (cp->cache_defrag == NULL || 1818 (avl_is_empty(&cp->cache_defrag->kmd_moves_pending) && 1819 !(sp->slab_flags & KMEM_SLAB_MOVE_PENDING))) { 1820 cp->cache_slab_destroy++; 1821 mutex_exit(&cp->cache_lock); 1822 kmem_slab_destroy(cp, sp); 1823 } else { 1824 list_t *deadlist = &cp->cache_defrag->kmd_deadlist; 1825 /* 1826 * Slabs are inserted at both ends of the deadlist to 1827 * distinguish between slabs freed while move callbacks 1828 * are pending (list head) and a slab freed while the 1829 * lock is dropped in kmem_move_buffers() (list tail) so 1830 * that in both cases slab_destroy() is called from the 1831 * right context. 1832 */ 1833 if (sp->slab_flags & KMEM_SLAB_MOVE_PENDING) { 1834 list_insert_tail(deadlist, sp); 1835 } else { 1836 list_insert_head(deadlist, sp); 1837 } 1838 cp->cache_defrag->kmd_deadcount++; 1839 mutex_exit(&cp->cache_lock); 1840 } 1841 return; 1842 } 1843 1844 if (bcp->bc_next == NULL) { 1845 /* Transition the slab from completely allocated to partial. */ 1846 ASSERT(sp->slab_refcnt == (sp->slab_chunks - 1)); 1847 ASSERT(sp->slab_chunks > 1); 1848 list_remove(&cp->cache_complete_slabs, sp); 1849 cp->cache_complete_slab_count--; 1850 avl_add(&cp->cache_partial_slabs, sp); 1851 } else { 1852 #ifdef DEBUG 1853 if (avl_update_gt(&cp->cache_partial_slabs, sp)) { 1854 KMEM_STAT_ADD(kmem_move_stats.kms_avl_update); 1855 } else { 1856 KMEM_STAT_ADD(kmem_move_stats.kms_avl_noupdate); 1857 } 1858 #else 1859 (void) avl_update_gt(&cp->cache_partial_slabs, sp); 1860 #endif 1861 } 1862 1863 ASSERT((cp->cache_slab_create - cp->cache_slab_destroy) == 1864 (cp->cache_complete_slab_count + 1865 avl_numnodes(&cp->cache_partial_slabs) + 1866 (cp->cache_defrag == NULL ? 0 : cp->cache_defrag->kmd_deadcount))); 1867 mutex_exit(&cp->cache_lock); 1868 } 1869 1870 /* 1871 * Return -1 if kmem_error, 1 if constructor fails, 0 if successful. 1872 */ 1873 static int 1874 kmem_cache_alloc_debug(kmem_cache_t *cp, void *buf, int kmflag, int construct, 1875 caddr_t caller) 1876 { 1877 kmem_buftag_t *btp = KMEM_BUFTAG(cp, buf); 1878 kmem_bufctl_audit_t *bcp = (kmem_bufctl_audit_t *)btp->bt_bufctl; 1879 uint32_t mtbf; 1880 1881 if (btp->bt_bxstat != ((intptr_t)bcp ^ KMEM_BUFTAG_FREE)) { 1882 kmem_error(KMERR_BADBUFTAG, cp, buf); 1883 return (-1); 1884 } 1885 1886 btp->bt_bxstat = (intptr_t)bcp ^ KMEM_BUFTAG_ALLOC; 1887 1888 if ((cp->cache_flags & KMF_HASH) && bcp->bc_addr != buf) { 1889 kmem_error(KMERR_BADBUFCTL, cp, buf); 1890 return (-1); 1891 } 1892 1893 if (cp->cache_flags & KMF_DEADBEEF) { 1894 if (!construct && (cp->cache_flags & KMF_LITE)) { 1895 if (*(uint64_t *)buf != KMEM_FREE_PATTERN) { 1896 kmem_error(KMERR_MODIFIED, cp, buf); 1897 return (-1); 1898 } 1899 if (cp->cache_constructor != NULL) 1900 *(uint64_t *)buf = btp->bt_redzone; 1901 else 1902 *(uint64_t *)buf = KMEM_UNINITIALIZED_PATTERN; 1903 } else { 1904 construct = 1; 1905 if (verify_and_copy_pattern(KMEM_FREE_PATTERN, 1906 KMEM_UNINITIALIZED_PATTERN, buf, 1907 cp->cache_verify)) { 1908 kmem_error(KMERR_MODIFIED, cp, buf); 1909 return (-1); 1910 } 1911 } 1912 } 1913 btp->bt_redzone = KMEM_REDZONE_PATTERN; 1914 1915 if ((mtbf = kmem_mtbf | cp->cache_mtbf) != 0 && 1916 gethrtime() % mtbf == 0 && 1917 (kmflag & (KM_NOSLEEP | KM_PANIC)) == KM_NOSLEEP) { 1918 kmem_log_event(kmem_failure_log, cp, NULL, NULL); 1919 if (!construct && cp->cache_destructor != NULL) 1920 cp->cache_destructor(buf, cp->cache_private); 1921 } else { 1922 mtbf = 0; 1923 } 1924 1925 if (mtbf || (construct && cp->cache_constructor != NULL && 1926 cp->cache_constructor(buf, cp->cache_private, kmflag) != 0)) { 1927 atomic_add_64(&cp->cache_alloc_fail, 1); 1928 btp->bt_bxstat = (intptr_t)bcp ^ KMEM_BUFTAG_FREE; 1929 if (cp->cache_flags & KMF_DEADBEEF) 1930 copy_pattern(KMEM_FREE_PATTERN, buf, cp->cache_verify); 1931 kmem_slab_free(cp, buf); 1932 return (1); 1933 } 1934 1935 if (cp->cache_flags & KMF_AUDIT) { 1936 KMEM_AUDIT(kmem_transaction_log, cp, bcp); 1937 } 1938 1939 if ((cp->cache_flags & KMF_LITE) && 1940 !(cp->cache_cflags & KMC_KMEM_ALLOC)) { 1941 KMEM_BUFTAG_LITE_ENTER(btp, kmem_lite_count, caller); 1942 } 1943 1944 return (0); 1945 } 1946 1947 static int 1948 kmem_cache_free_debug(kmem_cache_t *cp, void *buf, caddr_t caller) 1949 { 1950 kmem_buftag_t *btp = KMEM_BUFTAG(cp, buf); 1951 kmem_bufctl_audit_t *bcp = (kmem_bufctl_audit_t *)btp->bt_bufctl; 1952 kmem_slab_t *sp; 1953 1954 if (btp->bt_bxstat != ((intptr_t)bcp ^ KMEM_BUFTAG_ALLOC)) { 1955 if (btp->bt_bxstat == ((intptr_t)bcp ^ KMEM_BUFTAG_FREE)) { 1956 kmem_error(KMERR_DUPFREE, cp, buf); 1957 return (-1); 1958 } 1959 sp = kmem_findslab(cp, buf); 1960 if (sp == NULL || sp->slab_cache != cp) 1961 kmem_error(KMERR_BADADDR, cp, buf); 1962 else 1963 kmem_error(KMERR_REDZONE, cp, buf); 1964 return (-1); 1965 } 1966 1967 btp->bt_bxstat = (intptr_t)bcp ^ KMEM_BUFTAG_FREE; 1968 1969 if ((cp->cache_flags & KMF_HASH) && bcp->bc_addr != buf) { 1970 kmem_error(KMERR_BADBUFCTL, cp, buf); 1971 return (-1); 1972 } 1973 1974 if (btp->bt_redzone != KMEM_REDZONE_PATTERN) { 1975 kmem_error(KMERR_REDZONE, cp, buf); 1976 return (-1); 1977 } 1978 1979 if (cp->cache_flags & KMF_AUDIT) { 1980 if (cp->cache_flags & KMF_CONTENTS) 1981 bcp->bc_contents = kmem_log_enter(kmem_content_log, 1982 buf, cp->cache_contents); 1983 KMEM_AUDIT(kmem_transaction_log, cp, bcp); 1984 } 1985 1986 if ((cp->cache_flags & KMF_LITE) && 1987 !(cp->cache_cflags & KMC_KMEM_ALLOC)) { 1988 KMEM_BUFTAG_LITE_ENTER(btp, kmem_lite_count, caller); 1989 } 1990 1991 if (cp->cache_flags & KMF_DEADBEEF) { 1992 if (cp->cache_flags & KMF_LITE) 1993 btp->bt_redzone = *(uint64_t *)buf; 1994 else if (cp->cache_destructor != NULL) 1995 cp->cache_destructor(buf, cp->cache_private); 1996 1997 copy_pattern(KMEM_FREE_PATTERN, buf, cp->cache_verify); 1998 } 1999 2000 return (0); 2001 } 2002 2003 /* 2004 * Free each object in magazine mp to cp's slab layer, and free mp itself. 2005 */ 2006 static void 2007 kmem_magazine_destroy(kmem_cache_t *cp, kmem_magazine_t *mp, int nrounds) 2008 { 2009 int round; 2010 2011 ASSERT(!list_link_active(&cp->cache_link) || 2012 taskq_member(kmem_taskq, curthread)); 2013 2014 for (round = 0; round < nrounds; round++) { 2015 void *buf = mp->mag_round[round]; 2016 2017 if (cp->cache_flags & KMF_DEADBEEF) { 2018 if (verify_pattern(KMEM_FREE_PATTERN, buf, 2019 cp->cache_verify) != NULL) { 2020 kmem_error(KMERR_MODIFIED, cp, buf); 2021 continue; 2022 } 2023 if ((cp->cache_flags & KMF_LITE) && 2024 cp->cache_destructor != NULL) { 2025 kmem_buftag_t *btp = KMEM_BUFTAG(cp, buf); 2026 *(uint64_t *)buf = btp->bt_redzone; 2027 cp->cache_destructor(buf, cp->cache_private); 2028 *(uint64_t *)buf = KMEM_FREE_PATTERN; 2029 } 2030 } else if (cp->cache_destructor != NULL) { 2031 cp->cache_destructor(buf, cp->cache_private); 2032 } 2033 2034 kmem_slab_free(cp, buf); 2035 } 2036 ASSERT(KMEM_MAGAZINE_VALID(cp, mp)); 2037 kmem_cache_free(cp->cache_magtype->mt_cache, mp); 2038 } 2039 2040 /* 2041 * Allocate a magazine from the depot. 2042 */ 2043 static kmem_magazine_t * 2044 kmem_depot_alloc(kmem_cache_t *cp, kmem_maglist_t *mlp) 2045 { 2046 kmem_magazine_t *mp; 2047 2048 /* 2049 * If we can't get the depot lock without contention, 2050 * update our contention count. We use the depot 2051 * contention rate to determine whether we need to 2052 * increase the magazine size for better scalability. 2053 */ 2054 if (!mutex_tryenter(&cp->cache_depot_lock)) { 2055 mutex_enter(&cp->cache_depot_lock); 2056 cp->cache_depot_contention++; 2057 } 2058 2059 if ((mp = mlp->ml_list) != NULL) { 2060 ASSERT(KMEM_MAGAZINE_VALID(cp, mp)); 2061 mlp->ml_list = mp->mag_next; 2062 if (--mlp->ml_total < mlp->ml_min) 2063 mlp->ml_min = mlp->ml_total; 2064 mlp->ml_alloc++; 2065 } 2066 2067 mutex_exit(&cp->cache_depot_lock); 2068 2069 return (mp); 2070 } 2071 2072 /* 2073 * Free a magazine to the depot. 2074 */ 2075 static void 2076 kmem_depot_free(kmem_cache_t *cp, kmem_maglist_t *mlp, kmem_magazine_t *mp) 2077 { 2078 mutex_enter(&cp->cache_depot_lock); 2079 ASSERT(KMEM_MAGAZINE_VALID(cp, mp)); 2080 mp->mag_next = mlp->ml_list; 2081 mlp->ml_list = mp; 2082 mlp->ml_total++; 2083 mutex_exit(&cp->cache_depot_lock); 2084 } 2085 2086 /* 2087 * Update the working set statistics for cp's depot. 2088 */ 2089 static void 2090 kmem_depot_ws_update(kmem_cache_t *cp) 2091 { 2092 mutex_enter(&cp->cache_depot_lock); 2093 cp->cache_full.ml_reaplimit = cp->cache_full.ml_min; 2094 cp->cache_full.ml_min = cp->cache_full.ml_total; 2095 cp->cache_empty.ml_reaplimit = cp->cache_empty.ml_min; 2096 cp->cache_empty.ml_min = cp->cache_empty.ml_total; 2097 mutex_exit(&cp->cache_depot_lock); 2098 } 2099 2100 /* 2101 * Reap all magazines that have fallen out of the depot's working set. 2102 */ 2103 static void 2104 kmem_depot_ws_reap(kmem_cache_t *cp) 2105 { 2106 long reap; 2107 kmem_magazine_t *mp; 2108 2109 ASSERT(!list_link_active(&cp->cache_link) || 2110 taskq_member(kmem_taskq, curthread)); 2111 2112 reap = MIN(cp->cache_full.ml_reaplimit, cp->cache_full.ml_min); 2113 while (reap-- && (mp = kmem_depot_alloc(cp, &cp->cache_full)) != NULL) 2114 kmem_magazine_destroy(cp, mp, cp->cache_magtype->mt_magsize); 2115 2116 reap = MIN(cp->cache_empty.ml_reaplimit, cp->cache_empty.ml_min); 2117 while (reap-- && (mp = kmem_depot_alloc(cp, &cp->cache_empty)) != NULL) 2118 kmem_magazine_destroy(cp, mp, 0); 2119 } 2120 2121 static void 2122 kmem_cpu_reload(kmem_cpu_cache_t *ccp, kmem_magazine_t *mp, int rounds) 2123 { 2124 ASSERT((ccp->cc_loaded == NULL && ccp->cc_rounds == -1) || 2125 (ccp->cc_loaded && ccp->cc_rounds + rounds == ccp->cc_magsize)); 2126 ASSERT(ccp->cc_magsize > 0); 2127 2128 ccp->cc_ploaded = ccp->cc_loaded; 2129 ccp->cc_prounds = ccp->cc_rounds; 2130 ccp->cc_loaded = mp; 2131 ccp->cc_rounds = rounds; 2132 } 2133 2134 /* 2135 * Allocate a constructed object from cache cp. 2136 */ 2137 void * 2138 kmem_cache_alloc(kmem_cache_t *cp, int kmflag) 2139 { 2140 kmem_cpu_cache_t *ccp = KMEM_CPU_CACHE(cp); 2141 kmem_magazine_t *fmp; 2142 void *buf; 2143 2144 mutex_enter(&ccp->cc_lock); 2145 for (;;) { 2146 /* 2147 * If there's an object available in the current CPU's 2148 * loaded magazine, just take it and return. 2149 */ 2150 if (ccp->cc_rounds > 0) { 2151 buf = ccp->cc_loaded->mag_round[--ccp->cc_rounds]; 2152 ccp->cc_alloc++; 2153 mutex_exit(&ccp->cc_lock); 2154 if ((ccp->cc_flags & KMF_BUFTAG) && 2155 kmem_cache_alloc_debug(cp, buf, kmflag, 0, 2156 caller()) != 0) { 2157 if (kmflag & KM_NOSLEEP) 2158 return (NULL); 2159 mutex_enter(&ccp->cc_lock); 2160 continue; 2161 } 2162 return (buf); 2163 } 2164 2165 /* 2166 * The loaded magazine is empty. If the previously loaded 2167 * magazine was full, exchange them and try again. 2168 */ 2169 if (ccp->cc_prounds > 0) { 2170 kmem_cpu_reload(ccp, ccp->cc_ploaded, ccp->cc_prounds); 2171 continue; 2172 } 2173 2174 /* 2175 * If the magazine layer is disabled, break out now. 2176 */ 2177 if (ccp->cc_magsize == 0) 2178 break; 2179 2180 /* 2181 * Try to get a full magazine from the depot. 2182 */ 2183 fmp = kmem_depot_alloc(cp, &cp->cache_full); 2184 if (fmp != NULL) { 2185 if (ccp->cc_ploaded != NULL) 2186 kmem_depot_free(cp, &cp->cache_empty, 2187 ccp->cc_ploaded); 2188 kmem_cpu_reload(ccp, fmp, ccp->cc_magsize); 2189 continue; 2190 } 2191 2192 /* 2193 * There are no full magazines in the depot, 2194 * so fall through to the slab layer. 2195 */ 2196 break; 2197 } 2198 mutex_exit(&ccp->cc_lock); 2199 2200 /* 2201 * We couldn't allocate a constructed object from the magazine layer, 2202 * so get a raw buffer from the slab layer and apply its constructor. 2203 */ 2204 buf = kmem_slab_alloc(cp, kmflag); 2205 2206 if (buf == NULL) 2207 return (NULL); 2208 2209 if (cp->cache_flags & KMF_BUFTAG) { 2210 /* 2211 * Make kmem_cache_alloc_debug() apply the constructor for us. 2212 */ 2213 int rc = kmem_cache_alloc_debug(cp, buf, kmflag, 1, caller()); 2214 if (rc != 0) { 2215 if (kmflag & KM_NOSLEEP) 2216 return (NULL); 2217 /* 2218 * kmem_cache_alloc_debug() detected corruption 2219 * but didn't panic (kmem_panic <= 0). We should not be 2220 * here because the constructor failed (indicated by a 2221 * return code of 1). Try again. 2222 */ 2223 ASSERT(rc == -1); 2224 return (kmem_cache_alloc(cp, kmflag)); 2225 } 2226 return (buf); 2227 } 2228 2229 if (cp->cache_constructor != NULL && 2230 cp->cache_constructor(buf, cp->cache_private, kmflag) != 0) { 2231 atomic_add_64(&cp->cache_alloc_fail, 1); 2232 kmem_slab_free(cp, buf); 2233 return (NULL); 2234 } 2235 2236 return (buf); 2237 } 2238 2239 /* 2240 * The freed argument tells whether or not kmem_cache_free_debug() has already 2241 * been called so that we can avoid the duplicate free error. For example, a 2242 * buffer on a magazine has already been freed by the client but is still 2243 * constructed. 2244 */ 2245 static void 2246 kmem_slab_free_constructed(kmem_cache_t *cp, void *buf, boolean_t freed) 2247 { 2248 if (!freed && (cp->cache_flags & KMF_BUFTAG)) 2249 if (kmem_cache_free_debug(cp, buf, caller()) == -1) 2250 return; 2251 2252 /* 2253 * Note that if KMF_DEADBEEF is in effect and KMF_LITE is not, 2254 * kmem_cache_free_debug() will have already applied the destructor. 2255 */ 2256 if ((cp->cache_flags & (KMF_DEADBEEF | KMF_LITE)) != KMF_DEADBEEF && 2257 cp->cache_destructor != NULL) { 2258 if (cp->cache_flags & KMF_DEADBEEF) { /* KMF_LITE implied */ 2259 kmem_buftag_t *btp = KMEM_BUFTAG(cp, buf); 2260 *(uint64_t *)buf = btp->bt_redzone; 2261 cp->cache_destructor(buf, cp->cache_private); 2262 *(uint64_t *)buf = KMEM_FREE_PATTERN; 2263 } else { 2264 cp->cache_destructor(buf, cp->cache_private); 2265 } 2266 } 2267 2268 kmem_slab_free(cp, buf); 2269 } 2270 2271 /* 2272 * Free a constructed object to cache cp. 2273 */ 2274 void 2275 kmem_cache_free(kmem_cache_t *cp, void *buf) 2276 { 2277 kmem_cpu_cache_t *ccp = KMEM_CPU_CACHE(cp); 2278 kmem_magazine_t *emp; 2279 kmem_magtype_t *mtp; 2280 2281 /* 2282 * The client must not free either of the buffers passed to the move 2283 * callback function. 2284 */ 2285 ASSERT(cp->cache_defrag == NULL || 2286 cp->cache_defrag->kmd_thread != curthread || 2287 (buf != cp->cache_defrag->kmd_from_buf && 2288 buf != cp->cache_defrag->kmd_to_buf)); 2289 2290 if (ccp->cc_flags & KMF_BUFTAG) 2291 if (kmem_cache_free_debug(cp, buf, caller()) == -1) 2292 return; 2293 2294 mutex_enter(&ccp->cc_lock); 2295 for (;;) { 2296 /* 2297 * If there's a slot available in the current CPU's 2298 * loaded magazine, just put the object there and return. 2299 */ 2300 if ((uint_t)ccp->cc_rounds < ccp->cc_magsize) { 2301 ccp->cc_loaded->mag_round[ccp->cc_rounds++] = buf; 2302 ccp->cc_free++; 2303 mutex_exit(&ccp->cc_lock); 2304 return; 2305 } 2306 2307 /* 2308 * The loaded magazine is full. If the previously loaded 2309 * magazine was empty, exchange them and try again. 2310 */ 2311 if (ccp->cc_prounds == 0) { 2312 kmem_cpu_reload(ccp, ccp->cc_ploaded, ccp->cc_prounds); 2313 continue; 2314 } 2315 2316 /* 2317 * If the magazine layer is disabled, break out now. 2318 */ 2319 if (ccp->cc_magsize == 0) 2320 break; 2321 2322 /* 2323 * Try to get an empty magazine from the depot. 2324 */ 2325 emp = kmem_depot_alloc(cp, &cp->cache_empty); 2326 if (emp != NULL) { 2327 if (ccp->cc_ploaded != NULL) 2328 kmem_depot_free(cp, &cp->cache_full, 2329 ccp->cc_ploaded); 2330 kmem_cpu_reload(ccp, emp, 0); 2331 continue; 2332 } 2333 2334 /* 2335 * There are no empty magazines in the depot, 2336 * so try to allocate a new one. We must drop all locks 2337 * across kmem_cache_alloc() because lower layers may 2338 * attempt to allocate from this cache. 2339 */ 2340 mtp = cp->cache_magtype; 2341 mutex_exit(&ccp->cc_lock); 2342 emp = kmem_cache_alloc(mtp->mt_cache, KM_NOSLEEP); 2343 mutex_enter(&ccp->cc_lock); 2344 2345 if (emp != NULL) { 2346 /* 2347 * We successfully allocated an empty magazine. 2348 * However, we had to drop ccp->cc_lock to do it, 2349 * so the cache's magazine size may have changed. 2350 * If so, free the magazine and try again. 2351 */ 2352 if (ccp->cc_magsize != mtp->mt_magsize) { 2353 mutex_exit(&ccp->cc_lock); 2354 kmem_cache_free(mtp->mt_cache, emp); 2355 mutex_enter(&ccp->cc_lock); 2356 continue; 2357 } 2358 2359 /* 2360 * We got a magazine of the right size. Add it to 2361 * the depot and try the whole dance again. 2362 */ 2363 kmem_depot_free(cp, &cp->cache_empty, emp); 2364 continue; 2365 } 2366 2367 /* 2368 * We couldn't allocate an empty magazine, 2369 * so fall through to the slab layer. 2370 */ 2371 break; 2372 } 2373 mutex_exit(&ccp->cc_lock); 2374 2375 /* 2376 * We couldn't free our constructed object to the magazine layer, 2377 * so apply its destructor and free it to the slab layer. 2378 */ 2379 kmem_slab_free_constructed(cp, buf, B_TRUE); 2380 } 2381 2382 void * 2383 kmem_zalloc(size_t size, int kmflag) 2384 { 2385 size_t index = (size - 1) >> KMEM_ALIGN_SHIFT; 2386 void *buf; 2387 2388 if (index < KMEM_MAXBUF >> KMEM_ALIGN_SHIFT) { 2389 kmem_cache_t *cp = kmem_alloc_table[index]; 2390 buf = kmem_cache_alloc(cp, kmflag); 2391 if (buf != NULL) { 2392 if (cp->cache_flags & KMF_BUFTAG) { 2393 kmem_buftag_t *btp = KMEM_BUFTAG(cp, buf); 2394 ((uint8_t *)buf)[size] = KMEM_REDZONE_BYTE; 2395 ((uint32_t *)btp)[1] = KMEM_SIZE_ENCODE(size); 2396 2397 if (cp->cache_flags & KMF_LITE) { 2398 KMEM_BUFTAG_LITE_ENTER(btp, 2399 kmem_lite_count, caller()); 2400 } 2401 } 2402 bzero(buf, size); 2403 } 2404 } else { 2405 buf = kmem_alloc(size, kmflag); 2406 if (buf != NULL) 2407 bzero(buf, size); 2408 } 2409 return (buf); 2410 } 2411 2412 void * 2413 kmem_alloc(size_t size, int kmflag) 2414 { 2415 size_t index = (size - 1) >> KMEM_ALIGN_SHIFT; 2416 void *buf; 2417 2418 if (index < KMEM_MAXBUF >> KMEM_ALIGN_SHIFT) { 2419 kmem_cache_t *cp = kmem_alloc_table[index]; 2420 buf = kmem_cache_alloc(cp, kmflag); 2421 if ((cp->cache_flags & KMF_BUFTAG) && buf != NULL) { 2422 kmem_buftag_t *btp = KMEM_BUFTAG(cp, buf); 2423 ((uint8_t *)buf)[size] = KMEM_REDZONE_BYTE; 2424 ((uint32_t *)btp)[1] = KMEM_SIZE_ENCODE(size); 2425 2426 if (cp->cache_flags & KMF_LITE) { 2427 KMEM_BUFTAG_LITE_ENTER(btp, kmem_lite_count, 2428 caller()); 2429 } 2430 } 2431 return (buf); 2432 } 2433 if (size == 0) 2434 return (NULL); 2435 buf = vmem_alloc(kmem_oversize_arena, size, kmflag & KM_VMFLAGS); 2436 if (buf == NULL) 2437 kmem_log_event(kmem_failure_log, NULL, NULL, (void *)size); 2438 return (buf); 2439 } 2440 2441 void 2442 kmem_free(void *buf, size_t size) 2443 { 2444 size_t index = (size - 1) >> KMEM_ALIGN_SHIFT; 2445 2446 if (index < KMEM_MAXBUF >> KMEM_ALIGN_SHIFT) { 2447 kmem_cache_t *cp = kmem_alloc_table[index]; 2448 if (cp->cache_flags & KMF_BUFTAG) { 2449 kmem_buftag_t *btp = KMEM_BUFTAG(cp, buf); 2450 uint32_t *ip = (uint32_t *)btp; 2451 if (ip[1] != KMEM_SIZE_ENCODE(size)) { 2452 if (*(uint64_t *)buf == KMEM_FREE_PATTERN) { 2453 kmem_error(KMERR_DUPFREE, cp, buf); 2454 return; 2455 } 2456 if (KMEM_SIZE_VALID(ip[1])) { 2457 ip[0] = KMEM_SIZE_ENCODE(size); 2458 kmem_error(KMERR_BADSIZE, cp, buf); 2459 } else { 2460 kmem_error(KMERR_REDZONE, cp, buf); 2461 } 2462 return; 2463 } 2464 if (((uint8_t *)buf)[size] != KMEM_REDZONE_BYTE) { 2465 kmem_error(KMERR_REDZONE, cp, buf); 2466 return; 2467 } 2468 btp->bt_redzone = KMEM_REDZONE_PATTERN; 2469 if (cp->cache_flags & KMF_LITE) { 2470 KMEM_BUFTAG_LITE_ENTER(btp, kmem_lite_count, 2471 caller()); 2472 } 2473 } 2474 kmem_cache_free(cp, buf); 2475 } else { 2476 if (buf == NULL && size == 0) 2477 return; 2478 vmem_free(kmem_oversize_arena, buf, size); 2479 } 2480 } 2481 2482 void * 2483 kmem_firewall_va_alloc(vmem_t *vmp, size_t size, int vmflag) 2484 { 2485 size_t realsize = size + vmp->vm_quantum; 2486 void *addr; 2487 2488 /* 2489 * Annoying edge case: if 'size' is just shy of ULONG_MAX, adding 2490 * vm_quantum will cause integer wraparound. Check for this, and 2491 * blow off the firewall page in this case. Note that such a 2492 * giant allocation (the entire kernel address space) can never 2493 * be satisfied, so it will either fail immediately (VM_NOSLEEP) 2494 * or sleep forever (VM_SLEEP). Thus, there is no need for a 2495 * corresponding check in kmem_firewall_va_free(). 2496 */ 2497 if (realsize < size) 2498 realsize = size; 2499 2500 /* 2501 * While boot still owns resource management, make sure that this 2502 * redzone virtual address allocation is properly accounted for in 2503 * OBPs "virtual-memory" "available" lists because we're 2504 * effectively claiming them for a red zone. If we don't do this, 2505 * the available lists become too fragmented and too large for the 2506 * current boot/kernel memory list interface. 2507 */ 2508 addr = vmem_alloc(vmp, realsize, vmflag | VM_NEXTFIT); 2509 2510 if (addr != NULL && kvseg.s_base == NULL && realsize != size) 2511 (void) boot_virt_alloc((char *)addr + size, vmp->vm_quantum); 2512 2513 return (addr); 2514 } 2515 2516 void 2517 kmem_firewall_va_free(vmem_t *vmp, void *addr, size_t size) 2518 { 2519 ASSERT((kvseg.s_base == NULL ? 2520 va_to_pfn((char *)addr + size) : 2521 hat_getpfnum(kas.a_hat, (caddr_t)addr + size)) == PFN_INVALID); 2522 2523 vmem_free(vmp, addr, size + vmp->vm_quantum); 2524 } 2525 2526 /* 2527 * Try to allocate at least `size' bytes of memory without sleeping or 2528 * panicking. Return actual allocated size in `asize'. If allocation failed, 2529 * try final allocation with sleep or panic allowed. 2530 */ 2531 void * 2532 kmem_alloc_tryhard(size_t size, size_t *asize, int kmflag) 2533 { 2534 void *p; 2535 2536 *asize = P2ROUNDUP(size, KMEM_ALIGN); 2537 do { 2538 p = kmem_alloc(*asize, (kmflag | KM_NOSLEEP) & ~KM_PANIC); 2539 if (p != NULL) 2540 return (p); 2541 *asize += KMEM_ALIGN; 2542 } while (*asize <= PAGESIZE); 2543 2544 *asize = P2ROUNDUP(size, KMEM_ALIGN); 2545 return (kmem_alloc(*asize, kmflag)); 2546 } 2547 2548 /* 2549 * Reclaim all unused memory from a cache. 2550 */ 2551 static void 2552 kmem_cache_reap(kmem_cache_t *cp) 2553 { 2554 ASSERT(taskq_member(kmem_taskq, curthread)); 2555 2556 /* 2557 * Ask the cache's owner to free some memory if possible. 2558 * The idea is to handle things like the inode cache, which 2559 * typically sits on a bunch of memory that it doesn't truly 2560 * *need*. Reclaim policy is entirely up to the owner; this 2561 * callback is just an advisory plea for help. 2562 */ 2563 if (cp->cache_reclaim != NULL) { 2564 long delta; 2565 2566 /* 2567 * Reclaimed memory should be reapable (not included in the 2568 * depot's working set). 2569 */ 2570 delta = cp->cache_full.ml_total; 2571 cp->cache_reclaim(cp->cache_private); 2572 delta = cp->cache_full.ml_total - delta; 2573 if (delta > 0) { 2574 mutex_enter(&cp->cache_depot_lock); 2575 cp->cache_full.ml_reaplimit += delta; 2576 cp->cache_full.ml_min += delta; 2577 mutex_exit(&cp->cache_depot_lock); 2578 } 2579 } 2580 2581 kmem_depot_ws_reap(cp); 2582 2583 if (cp->cache_defrag != NULL && !kmem_move_noreap) { 2584 kmem_cache_defrag(cp); 2585 } 2586 } 2587 2588 static void 2589 kmem_reap_timeout(void *flag_arg) 2590 { 2591 uint32_t *flag = (uint32_t *)flag_arg; 2592 2593 ASSERT(flag == &kmem_reaping || flag == &kmem_reaping_idspace); 2594 *flag = 0; 2595 } 2596 2597 static void 2598 kmem_reap_done(void *flag) 2599 { 2600 (void) timeout(kmem_reap_timeout, flag, kmem_reap_interval); 2601 } 2602 2603 static void 2604 kmem_reap_start(void *flag) 2605 { 2606 ASSERT(flag == &kmem_reaping || flag == &kmem_reaping_idspace); 2607 2608 if (flag == &kmem_reaping) { 2609 kmem_cache_applyall(kmem_cache_reap, kmem_taskq, TQ_NOSLEEP); 2610 /* 2611 * if we have segkp under heap, reap segkp cache. 2612 */ 2613 if (segkp_fromheap) 2614 segkp_cache_free(); 2615 } 2616 else 2617 kmem_cache_applyall_id(kmem_cache_reap, kmem_taskq, TQ_NOSLEEP); 2618 2619 /* 2620 * We use taskq_dispatch() to schedule a timeout to clear 2621 * the flag so that kmem_reap() becomes self-throttling: 2622 * we won't reap again until the current reap completes *and* 2623 * at least kmem_reap_interval ticks have elapsed. 2624 */ 2625 if (!taskq_dispatch(kmem_taskq, kmem_reap_done, flag, TQ_NOSLEEP)) 2626 kmem_reap_done(flag); 2627 } 2628 2629 static void 2630 kmem_reap_common(void *flag_arg) 2631 { 2632 uint32_t *flag = (uint32_t *)flag_arg; 2633 2634 if (MUTEX_HELD(&kmem_cache_lock) || kmem_taskq == NULL || 2635 cas32(flag, 0, 1) != 0) 2636 return; 2637 2638 /* 2639 * It may not be kosher to do memory allocation when a reap is called 2640 * is called (for example, if vmem_populate() is in the call chain). 2641 * So we start the reap going with a TQ_NOALLOC dispatch. If the 2642 * dispatch fails, we reset the flag, and the next reap will try again. 2643 */ 2644 if (!taskq_dispatch(kmem_taskq, kmem_reap_start, flag, TQ_NOALLOC)) 2645 *flag = 0; 2646 } 2647 2648 /* 2649 * Reclaim all unused memory from all caches. Called from the VM system 2650 * when memory gets tight. 2651 */ 2652 void 2653 kmem_reap(void) 2654 { 2655 kmem_reap_common(&kmem_reaping); 2656 } 2657 2658 /* 2659 * Reclaim all unused memory from identifier arenas, called when a vmem 2660 * arena not back by memory is exhausted. Since reaping memory-backed caches 2661 * cannot help with identifier exhaustion, we avoid both a large amount of 2662 * work and unwanted side-effects from reclaim callbacks. 2663 */ 2664 void 2665 kmem_reap_idspace(void) 2666 { 2667 kmem_reap_common(&kmem_reaping_idspace); 2668 } 2669 2670 /* 2671 * Purge all magazines from a cache and set its magazine limit to zero. 2672 * All calls are serialized by the kmem_taskq lock, except for the final 2673 * call from kmem_cache_destroy(). 2674 */ 2675 static void 2676 kmem_cache_magazine_purge(kmem_cache_t *cp) 2677 { 2678 kmem_cpu_cache_t *ccp; 2679 kmem_magazine_t *mp, *pmp; 2680 int rounds, prounds, cpu_seqid; 2681 2682 ASSERT(!list_link_active(&cp->cache_link) || 2683 taskq_member(kmem_taskq, curthread)); 2684 ASSERT(MUTEX_NOT_HELD(&cp->cache_lock)); 2685 2686 for (cpu_seqid = 0; cpu_seqid < max_ncpus; cpu_seqid++) { 2687 ccp = &cp->cache_cpu[cpu_seqid]; 2688 2689 mutex_enter(&ccp->cc_lock); 2690 mp = ccp->cc_loaded; 2691 pmp = ccp->cc_ploaded; 2692 rounds = ccp->cc_rounds; 2693 prounds = ccp->cc_prounds; 2694 ccp->cc_loaded = NULL; 2695 ccp->cc_ploaded = NULL; 2696 ccp->cc_rounds = -1; 2697 ccp->cc_prounds = -1; 2698 ccp->cc_magsize = 0; 2699 mutex_exit(&ccp->cc_lock); 2700 2701 if (mp) 2702 kmem_magazine_destroy(cp, mp, rounds); 2703 if (pmp) 2704 kmem_magazine_destroy(cp, pmp, prounds); 2705 } 2706 2707 /* 2708 * Updating the working set statistics twice in a row has the 2709 * effect of setting the working set size to zero, so everything 2710 * is eligible for reaping. 2711 */ 2712 kmem_depot_ws_update(cp); 2713 kmem_depot_ws_update(cp); 2714 2715 kmem_depot_ws_reap(cp); 2716 } 2717 2718 /* 2719 * Enable per-cpu magazines on a cache. 2720 */ 2721 static void 2722 kmem_cache_magazine_enable(kmem_cache_t *cp) 2723 { 2724 int cpu_seqid; 2725 2726 if (cp->cache_flags & KMF_NOMAGAZINE) 2727 return; 2728 2729 for (cpu_seqid = 0; cpu_seqid < max_ncpus; cpu_seqid++) { 2730 kmem_cpu_cache_t *ccp = &cp->cache_cpu[cpu_seqid]; 2731 mutex_enter(&ccp->cc_lock); 2732 ccp->cc_magsize = cp->cache_magtype->mt_magsize; 2733 mutex_exit(&ccp->cc_lock); 2734 } 2735 2736 } 2737 2738 /* 2739 * Reap (almost) everything right now. See kmem_cache_magazine_purge() 2740 * for explanation of the back-to-back kmem_depot_ws_update() calls. 2741 */ 2742 void 2743 kmem_cache_reap_now(kmem_cache_t *cp) 2744 { 2745 ASSERT(list_link_active(&cp->cache_link)); 2746 2747 kmem_depot_ws_update(cp); 2748 kmem_depot_ws_update(cp); 2749 2750 (void) taskq_dispatch(kmem_taskq, 2751 (task_func_t *)kmem_depot_ws_reap, cp, TQ_SLEEP); 2752 taskq_wait(kmem_taskq); 2753 } 2754 2755 /* 2756 * Recompute a cache's magazine size. The trade-off is that larger magazines 2757 * provide a higher transfer rate with the depot, while smaller magazines 2758 * reduce memory consumption. Magazine resizing is an expensive operation; 2759 * it should not be done frequently. 2760 * 2761 * Changes to the magazine size are serialized by the kmem_taskq lock. 2762 * 2763 * Note: at present this only grows the magazine size. It might be useful 2764 * to allow shrinkage too. 2765 */ 2766 static void 2767 kmem_cache_magazine_resize(kmem_cache_t *cp) 2768 { 2769 kmem_magtype_t *mtp = cp->cache_magtype; 2770 2771 ASSERT(taskq_member(kmem_taskq, curthread)); 2772 2773 if (cp->cache_chunksize < mtp->mt_maxbuf) { 2774 kmem_cache_magazine_purge(cp); 2775 mutex_enter(&cp->cache_depot_lock); 2776 cp->cache_magtype = ++mtp; 2777 cp->cache_depot_contention_prev = 2778 cp->cache_depot_contention + INT_MAX; 2779 mutex_exit(&cp->cache_depot_lock); 2780 kmem_cache_magazine_enable(cp); 2781 } 2782 } 2783 2784 /* 2785 * Rescale a cache's hash table, so that the table size is roughly the 2786 * cache size. We want the average lookup time to be extremely small. 2787 */ 2788 static void 2789 kmem_hash_rescale(kmem_cache_t *cp) 2790 { 2791 kmem_bufctl_t **old_table, **new_table, *bcp; 2792 size_t old_size, new_size, h; 2793 2794 ASSERT(taskq_member(kmem_taskq, curthread)); 2795 2796 new_size = MAX(KMEM_HASH_INITIAL, 2797 1 << (highbit(3 * cp->cache_buftotal + 4) - 2)); 2798 old_size = cp->cache_hash_mask + 1; 2799 2800 if ((old_size >> 1) <= new_size && new_size <= (old_size << 1)) 2801 return; 2802 2803 new_table = vmem_alloc(kmem_hash_arena, new_size * sizeof (void *), 2804 VM_NOSLEEP); 2805 if (new_table == NULL) 2806 return; 2807 bzero(new_table, new_size * sizeof (void *)); 2808 2809 mutex_enter(&cp->cache_lock); 2810 2811 old_size = cp->cache_hash_mask + 1; 2812 old_table = cp->cache_hash_table; 2813 2814 cp->cache_hash_mask = new_size - 1; 2815 cp->cache_hash_table = new_table; 2816 cp->cache_rescale++; 2817 2818 for (h = 0; h < old_size; h++) { 2819 bcp = old_table[h]; 2820 while (bcp != NULL) { 2821 void *addr = bcp->bc_addr; 2822 kmem_bufctl_t *next_bcp = bcp->bc_next; 2823 kmem_bufctl_t **hash_bucket = KMEM_HASH(cp, addr); 2824 bcp->bc_next = *hash_bucket; 2825 *hash_bucket = bcp; 2826 bcp = next_bcp; 2827 } 2828 } 2829 2830 mutex_exit(&cp->cache_lock); 2831 2832 vmem_free(kmem_hash_arena, old_table, old_size * sizeof (void *)); 2833 } 2834 2835 /* 2836 * Perform periodic maintenance on a cache: hash rescaling, depot working-set 2837 * update, magazine resizing, and slab consolidation. 2838 */ 2839 static void 2840 kmem_cache_update(kmem_cache_t *cp) 2841 { 2842 int need_hash_rescale = 0; 2843 int need_magazine_resize = 0; 2844 2845 ASSERT(MUTEX_HELD(&kmem_cache_lock)); 2846 2847 /* 2848 * If the cache has become much larger or smaller than its hash table, 2849 * fire off a request to rescale the hash table. 2850 */ 2851 mutex_enter(&cp->cache_lock); 2852 2853 if ((cp->cache_flags & KMF_HASH) && 2854 (cp->cache_buftotal > (cp->cache_hash_mask << 1) || 2855 (cp->cache_buftotal < (cp->cache_hash_mask >> 1) && 2856 cp->cache_hash_mask > KMEM_HASH_INITIAL))) 2857 need_hash_rescale = 1; 2858 2859 mutex_exit(&cp->cache_lock); 2860 2861 /* 2862 * Update the depot working set statistics. 2863 */ 2864 kmem_depot_ws_update(cp); 2865 2866 /* 2867 * If there's a lot of contention in the depot, 2868 * increase the magazine size. 2869 */ 2870 mutex_enter(&cp->cache_depot_lock); 2871 2872 if (cp->cache_chunksize < cp->cache_magtype->mt_maxbuf && 2873 (int)(cp->cache_depot_contention - 2874 cp->cache_depot_contention_prev) > kmem_depot_contention) 2875 need_magazine_resize = 1; 2876 2877 cp->cache_depot_contention_prev = cp->cache_depot_contention; 2878 2879 mutex_exit(&cp->cache_depot_lock); 2880 2881 if (need_hash_rescale) 2882 (void) taskq_dispatch(kmem_taskq, 2883 (task_func_t *)kmem_hash_rescale, cp, TQ_NOSLEEP); 2884 2885 if (need_magazine_resize) 2886 (void) taskq_dispatch(kmem_taskq, 2887 (task_func_t *)kmem_cache_magazine_resize, cp, TQ_NOSLEEP); 2888 2889 if (cp->cache_defrag != NULL) 2890 (void) taskq_dispatch(kmem_taskq, 2891 (task_func_t *)kmem_cache_scan, cp, TQ_NOSLEEP); 2892 } 2893 2894 static void 2895 kmem_update_timeout(void *dummy) 2896 { 2897 static void kmem_update(void *); 2898 2899 (void) timeout(kmem_update, dummy, kmem_reap_interval); 2900 } 2901 2902 static void 2903 kmem_update(void *dummy) 2904 { 2905 kmem_cache_applyall(kmem_cache_update, NULL, TQ_NOSLEEP); 2906 2907 /* 2908 * We use taskq_dispatch() to reschedule the timeout so that 2909 * kmem_update() becomes self-throttling: it won't schedule 2910 * new tasks until all previous tasks have completed. 2911 */ 2912 if (!taskq_dispatch(kmem_taskq, kmem_update_timeout, dummy, TQ_NOSLEEP)) 2913 kmem_update_timeout(NULL); 2914 } 2915 2916 static int 2917 kmem_cache_kstat_update(kstat_t *ksp, int rw) 2918 { 2919 struct kmem_cache_kstat *kmcp = &kmem_cache_kstat; 2920 kmem_cache_t *cp = ksp->ks_private; 2921 uint64_t cpu_buf_avail; 2922 uint64_t buf_avail = 0; 2923 int cpu_seqid; 2924 2925 ASSERT(MUTEX_HELD(&kmem_cache_kstat_lock)); 2926 2927 if (rw == KSTAT_WRITE) 2928 return (EACCES); 2929 2930 mutex_enter(&cp->cache_lock); 2931 2932 kmcp->kmc_alloc_fail.value.ui64 = cp->cache_alloc_fail; 2933 kmcp->kmc_alloc.value.ui64 = cp->cache_slab_alloc; 2934 kmcp->kmc_free.value.ui64 = cp->cache_slab_free; 2935 kmcp->kmc_slab_alloc.value.ui64 = cp->cache_slab_alloc; 2936 kmcp->kmc_slab_free.value.ui64 = cp->cache_slab_free; 2937 2938 for (cpu_seqid = 0; cpu_seqid < max_ncpus; cpu_seqid++) { 2939 kmem_cpu_cache_t *ccp = &cp->cache_cpu[cpu_seqid]; 2940 2941 mutex_enter(&ccp->cc_lock); 2942 2943 cpu_buf_avail = 0; 2944 if (ccp->cc_rounds > 0) 2945 cpu_buf_avail += ccp->cc_rounds; 2946 if (ccp->cc_prounds > 0) 2947 cpu_buf_avail += ccp->cc_prounds; 2948 2949 kmcp->kmc_alloc.value.ui64 += ccp->cc_alloc; 2950 kmcp->kmc_free.value.ui64 += ccp->cc_free; 2951 buf_avail += cpu_buf_avail; 2952 2953 mutex_exit(&ccp->cc_lock); 2954 } 2955 2956 mutex_enter(&cp->cache_depot_lock); 2957 2958 kmcp->kmc_depot_alloc.value.ui64 = cp->cache_full.ml_alloc; 2959 kmcp->kmc_depot_free.value.ui64 = cp->cache_empty.ml_alloc; 2960 kmcp->kmc_depot_contention.value.ui64 = cp->cache_depot_contention; 2961 kmcp->kmc_full_magazines.value.ui64 = cp->cache_full.ml_total; 2962 kmcp->kmc_empty_magazines.value.ui64 = cp->cache_empty.ml_total; 2963 kmcp->kmc_magazine_size.value.ui64 = 2964 (cp->cache_flags & KMF_NOMAGAZINE) ? 2965 0 : cp->cache_magtype->mt_magsize; 2966 2967 kmcp->kmc_alloc.value.ui64 += cp->cache_full.ml_alloc; 2968 kmcp->kmc_free.value.ui64 += cp->cache_empty.ml_alloc; 2969 buf_avail += cp->cache_full.ml_total * cp->cache_magtype->mt_magsize; 2970 2971 mutex_exit(&cp->cache_depot_lock); 2972 2973 kmcp->kmc_buf_size.value.ui64 = cp->cache_bufsize; 2974 kmcp->kmc_align.value.ui64 = cp->cache_align; 2975 kmcp->kmc_chunk_size.value.ui64 = cp->cache_chunksize; 2976 kmcp->kmc_slab_size.value.ui64 = cp->cache_slabsize; 2977 kmcp->kmc_buf_constructed.value.ui64 = buf_avail; 2978 buf_avail += cp->cache_bufslab; 2979 kmcp->kmc_buf_avail.value.ui64 = buf_avail; 2980 kmcp->kmc_buf_inuse.value.ui64 = cp->cache_buftotal - buf_avail; 2981 kmcp->kmc_buf_total.value.ui64 = cp->cache_buftotal; 2982 kmcp->kmc_buf_max.value.ui64 = cp->cache_bufmax; 2983 kmcp->kmc_slab_create.value.ui64 = cp->cache_slab_create; 2984 kmcp->kmc_slab_destroy.value.ui64 = cp->cache_slab_destroy; 2985 kmcp->kmc_hash_size.value.ui64 = (cp->cache_flags & KMF_HASH) ? 2986 cp->cache_hash_mask + 1 : 0; 2987 kmcp->kmc_hash_lookup_depth.value.ui64 = cp->cache_lookup_depth; 2988 kmcp->kmc_hash_rescale.value.ui64 = cp->cache_rescale; 2989 kmcp->kmc_vmem_source.value.ui64 = cp->cache_arena->vm_id; 2990 2991 if (cp->cache_defrag == NULL) { 2992 kmcp->kmc_move_callbacks.value.ui64 = 0; 2993 kmcp->kmc_move_yes.value.ui64 = 0; 2994 kmcp->kmc_move_no.value.ui64 = 0; 2995 kmcp->kmc_move_later.value.ui64 = 0; 2996 kmcp->kmc_move_dont_need.value.ui64 = 0; 2997 kmcp->kmc_move_dont_know.value.ui64 = 0; 2998 kmcp->kmc_move_hunt_found.value.ui64 = 0; 2999 } else { 3000 kmem_defrag_t *kd = cp->cache_defrag; 3001 kmcp->kmc_move_callbacks.value.ui64 = kd->kmd_callbacks; 3002 kmcp->kmc_move_yes.value.ui64 = kd->kmd_yes; 3003 kmcp->kmc_move_no.value.ui64 = kd->kmd_no; 3004 kmcp->kmc_move_later.value.ui64 = kd->kmd_later; 3005 kmcp->kmc_move_dont_need.value.ui64 = kd->kmd_dont_need; 3006 kmcp->kmc_move_dont_know.value.ui64 = kd->kmd_dont_know; 3007 kmcp->kmc_move_hunt_found.value.ui64 = kd->kmd_hunt_found; 3008 } 3009 3010 mutex_exit(&cp->cache_lock); 3011 return (0); 3012 } 3013 3014 /* 3015 * Return a named statistic about a particular cache. 3016 * This shouldn't be called very often, so it's currently designed for 3017 * simplicity (leverages existing kstat support) rather than efficiency. 3018 */ 3019 uint64_t 3020 kmem_cache_stat(kmem_cache_t *cp, char *name) 3021 { 3022 int i; 3023 kstat_t *ksp = cp->cache_kstat; 3024 kstat_named_t *knp = (kstat_named_t *)&kmem_cache_kstat; 3025 uint64_t value = 0; 3026 3027 if (ksp != NULL) { 3028 mutex_enter(&kmem_cache_kstat_lock); 3029 (void) kmem_cache_kstat_update(ksp, KSTAT_READ); 3030 for (i = 0; i < ksp->ks_ndata; i++) { 3031 if (strcmp(knp[i].name, name) == 0) { 3032 value = knp[i].value.ui64; 3033 break; 3034 } 3035 } 3036 mutex_exit(&kmem_cache_kstat_lock); 3037 } 3038 return (value); 3039 } 3040 3041 /* 3042 * Return an estimate of currently available kernel heap memory. 3043 * On 32-bit systems, physical memory may exceed virtual memory, 3044 * we just truncate the result at 1GB. 3045 */ 3046 size_t 3047 kmem_avail(void) 3048 { 3049 spgcnt_t rmem = availrmem - tune.t_minarmem; 3050 spgcnt_t fmem = freemem - minfree; 3051 3052 return ((size_t)ptob(MIN(MAX(MIN(rmem, fmem), 0), 3053 1 << (30 - PAGESHIFT)))); 3054 } 3055 3056 /* 3057 * Return the maximum amount of memory that is (in theory) allocatable 3058 * from the heap. This may be used as an estimate only since there 3059 * is no guarentee this space will still be available when an allocation 3060 * request is made, nor that the space may be allocated in one big request 3061 * due to kernel heap fragmentation. 3062 */ 3063 size_t 3064 kmem_maxavail(void) 3065 { 3066 spgcnt_t pmem = availrmem - tune.t_minarmem; 3067 spgcnt_t vmem = btop(vmem_size(heap_arena, VMEM_FREE)); 3068 3069 return ((size_t)ptob(MAX(MIN(pmem, vmem), 0))); 3070 } 3071 3072 /* 3073 * Indicate whether memory-intensive kmem debugging is enabled. 3074 */ 3075 int 3076 kmem_debugging(void) 3077 { 3078 return (kmem_flags & (KMF_AUDIT | KMF_REDZONE)); 3079 } 3080 3081 /* binning function, sorts finely at the two extremes */ 3082 #define KMEM_PARTIAL_SLAB_WEIGHT(sp, binshift) \ 3083 ((((sp)->slab_refcnt <= (binshift)) || \ 3084 (((sp)->slab_chunks - (sp)->slab_refcnt) <= (binshift))) \ 3085 ? -(sp)->slab_refcnt \ 3086 : -((binshift) + ((sp)->slab_refcnt >> (binshift)))) 3087 3088 /* 3089 * Minimizing the number of partial slabs on the freelist minimizes 3090 * fragmentation (the ratio of unused buffers held by the slab layer). There are 3091 * two ways to get a slab off of the freelist: 1) free all the buffers on the 3092 * slab, and 2) allocate all the buffers on the slab. It follows that we want 3093 * the most-used slabs at the front of the list where they have the best chance 3094 * of being completely allocated, and the least-used slabs at a safe distance 3095 * from the front to improve the odds that the few remaining buffers will all be 3096 * freed before another allocation can tie up the slab. For that reason a slab 3097 * with a higher slab_refcnt sorts less than than a slab with a lower 3098 * slab_refcnt. 3099 * 3100 * However, if a slab has at least one buffer that is deemed unfreeable, we 3101 * would rather have that slab at the front of the list regardless of 3102 * slab_refcnt, since even one unfreeable buffer makes the entire slab 3103 * unfreeable. If the client returns KMEM_CBRC_NO in response to a cache_move() 3104 * callback, the slab is marked unfreeable for as long as it remains on the 3105 * freelist. 3106 */ 3107 static int 3108 kmem_partial_slab_cmp(const void *p0, const void *p1) 3109 { 3110 const kmem_cache_t *cp; 3111 const kmem_slab_t *s0 = p0; 3112 const kmem_slab_t *s1 = p1; 3113 int w0, w1; 3114 size_t binshift; 3115 3116 ASSERT(KMEM_SLAB_IS_PARTIAL(s0)); 3117 ASSERT(KMEM_SLAB_IS_PARTIAL(s1)); 3118 ASSERT(s0->slab_cache == s1->slab_cache); 3119 cp = s1->slab_cache; 3120 ASSERT(MUTEX_HELD(&cp->cache_lock)); 3121 binshift = cp->cache_partial_binshift; 3122 3123 /* weight of first slab */ 3124 w0 = KMEM_PARTIAL_SLAB_WEIGHT(s0, binshift); 3125 if (s0->slab_flags & KMEM_SLAB_NOMOVE) { 3126 w0 -= cp->cache_maxchunks; 3127 } 3128 3129 /* weight of second slab */ 3130 w1 = KMEM_PARTIAL_SLAB_WEIGHT(s1, binshift); 3131 if (s1->slab_flags & KMEM_SLAB_NOMOVE) { 3132 w1 -= cp->cache_maxchunks; 3133 } 3134 3135 if (w0 < w1) 3136 return (-1); 3137 if (w0 > w1) 3138 return (1); 3139 3140 /* compare pointer values */ 3141 if ((uintptr_t)s0 < (uintptr_t)s1) 3142 return (-1); 3143 if ((uintptr_t)s0 > (uintptr_t)s1) 3144 return (1); 3145 3146 return (0); 3147 } 3148 3149 static void 3150 kmem_check_destructor(kmem_cache_t *cp) 3151 { 3152 if (cp->cache_destructor == NULL) 3153 return; 3154 3155 /* 3156 * Assert that it is valid to call the destructor on a newly constructed 3157 * object without any intervening client code using the object. 3158 * Allocate from the slab layer to ensure that the client has not 3159 * touched the buffer. 3160 */ 3161 void *buf = kmem_slab_alloc(cp, KM_NOSLEEP); 3162 if (buf == NULL) 3163 return; 3164 3165 if (cp->cache_flags & KMF_BUFTAG) { 3166 if (kmem_cache_alloc_debug(cp, buf, KM_NOSLEEP, 1, 3167 caller()) != 0) 3168 return; 3169 } else if (cp->cache_constructor != NULL && 3170 cp->cache_constructor(buf, cp->cache_private, KM_NOSLEEP) != 0) { 3171 atomic_add_64(&cp->cache_alloc_fail, 1); 3172 kmem_slab_free(cp, buf); 3173 return; 3174 } 3175 3176 kmem_slab_free_constructed(cp, buf, B_FALSE); 3177 } 3178 3179 /* 3180 * It must be valid to call the destructor (if any) on a newly created object. 3181 * That is, the constructor (if any) must leave the object in a valid state for 3182 * the destructor. 3183 */ 3184 kmem_cache_t * 3185 kmem_cache_create( 3186 char *name, /* descriptive name for this cache */ 3187 size_t bufsize, /* size of the objects it manages */ 3188 size_t align, /* required object alignment */ 3189 int (*constructor)(void *, void *, int), /* object constructor */ 3190 void (*destructor)(void *, void *), /* object destructor */ 3191 void (*reclaim)(void *), /* memory reclaim callback */ 3192 void *private, /* pass-thru arg for constr/destr/reclaim */ 3193 vmem_t *vmp, /* vmem source for slab allocation */ 3194 int cflags) /* cache creation flags */ 3195 { 3196 int cpu_seqid; 3197 size_t chunksize; 3198 kmem_cache_t *cp; 3199 kmem_magtype_t *mtp; 3200 size_t csize = KMEM_CACHE_SIZE(max_ncpus); 3201 3202 #ifdef DEBUG 3203 /* 3204 * Cache names should conform to the rules for valid C identifiers 3205 */ 3206 if (!strident_valid(name)) { 3207 cmn_err(CE_CONT, 3208 "kmem_cache_create: '%s' is an invalid cache name\n" 3209 "cache names must conform to the rules for " 3210 "C identifiers\n", name); 3211 } 3212 #endif /* DEBUG */ 3213 3214 if (vmp == NULL) 3215 vmp = kmem_default_arena; 3216 3217 /* 3218 * If this kmem cache has an identifier vmem arena as its source, mark 3219 * it such to allow kmem_reap_idspace(). 3220 */ 3221 ASSERT(!(cflags & KMC_IDENTIFIER)); /* consumer should not set this */ 3222 if (vmp->vm_cflags & VMC_IDENTIFIER) 3223 cflags |= KMC_IDENTIFIER; 3224 3225 /* 3226 * Get a kmem_cache structure. We arrange that cp->cache_cpu[] 3227 * is aligned on a KMEM_CPU_CACHE_SIZE boundary to prevent 3228 * false sharing of per-CPU data. 3229 */ 3230 cp = vmem_xalloc(kmem_cache_arena, csize, KMEM_CPU_CACHE_SIZE, 3231 P2NPHASE(csize, KMEM_CPU_CACHE_SIZE), 0, NULL, NULL, VM_SLEEP); 3232 bzero(cp, csize); 3233 list_link_init(&cp->cache_link); 3234 3235 if (align == 0) 3236 align = KMEM_ALIGN; 3237 3238 /* 3239 * If we're not at least KMEM_ALIGN aligned, we can't use free 3240 * memory to hold bufctl information (because we can't safely 3241 * perform word loads and stores on it). 3242 */ 3243 if (align < KMEM_ALIGN) 3244 cflags |= KMC_NOTOUCH; 3245 3246 if ((align & (align - 1)) != 0 || align > vmp->vm_quantum) 3247 panic("kmem_cache_create: bad alignment %lu", align); 3248 3249 mutex_enter(&kmem_flags_lock); 3250 if (kmem_flags & KMF_RANDOMIZE) 3251 kmem_flags = (((kmem_flags | ~KMF_RANDOM) + 1) & KMF_RANDOM) | 3252 KMF_RANDOMIZE; 3253 cp->cache_flags = (kmem_flags | cflags) & KMF_DEBUG; 3254 mutex_exit(&kmem_flags_lock); 3255 3256 /* 3257 * Make sure all the various flags are reasonable. 3258 */ 3259 ASSERT(!(cflags & KMC_NOHASH) || !(cflags & KMC_NOTOUCH)); 3260 3261 if (cp->cache_flags & KMF_LITE) { 3262 if (bufsize >= kmem_lite_minsize && 3263 align <= kmem_lite_maxalign && 3264 P2PHASE(bufsize, kmem_lite_maxalign) != 0) { 3265 cp->cache_flags |= KMF_BUFTAG; 3266 cp->cache_flags &= ~(KMF_AUDIT | KMF_FIREWALL); 3267 } else { 3268 cp->cache_flags &= ~KMF_DEBUG; 3269 } 3270 } 3271 3272 if (cp->cache_flags & KMF_DEADBEEF) 3273 cp->cache_flags |= KMF_REDZONE; 3274 3275 if ((cflags & KMC_QCACHE) && (cp->cache_flags & KMF_AUDIT)) 3276 cp->cache_flags |= KMF_NOMAGAZINE; 3277 3278 if (cflags & KMC_NODEBUG) 3279 cp->cache_flags &= ~KMF_DEBUG; 3280 3281 if (cflags & KMC_NOTOUCH) 3282 cp->cache_flags &= ~KMF_TOUCH; 3283 3284 if (cflags & KMC_NOHASH) 3285 cp->cache_flags &= ~(KMF_AUDIT | KMF_FIREWALL); 3286 3287 if (cflags & KMC_NOMAGAZINE) 3288 cp->cache_flags |= KMF_NOMAGAZINE; 3289 3290 if ((cp->cache_flags & KMF_AUDIT) && !(cflags & KMC_NOTOUCH)) 3291 cp->cache_flags |= KMF_REDZONE; 3292 3293 if (!(cp->cache_flags & KMF_AUDIT)) 3294 cp->cache_flags &= ~KMF_CONTENTS; 3295 3296 if ((cp->cache_flags & KMF_BUFTAG) && bufsize >= kmem_minfirewall && 3297 !(cp->cache_flags & KMF_LITE) && !(cflags & KMC_NOHASH)) 3298 cp->cache_flags |= KMF_FIREWALL; 3299 3300 if (vmp != kmem_default_arena || kmem_firewall_arena == NULL) 3301 cp->cache_flags &= ~KMF_FIREWALL; 3302 3303 if (cp->cache_flags & KMF_FIREWALL) { 3304 cp->cache_flags &= ~KMF_BUFTAG; 3305 cp->cache_flags |= KMF_NOMAGAZINE; 3306 ASSERT(vmp == kmem_default_arena); 3307 vmp = kmem_firewall_arena; 3308 } 3309 3310 /* 3311 * Set cache properties. 3312 */ 3313 (void) strncpy(cp->cache_name, name, KMEM_CACHE_NAMELEN); 3314 strident_canon(cp->cache_name, KMEM_CACHE_NAMELEN + 1); 3315 cp->cache_bufsize = bufsize; 3316 cp->cache_align = align; 3317 cp->cache_constructor = constructor; 3318 cp->cache_destructor = destructor; 3319 cp->cache_reclaim = reclaim; 3320 cp->cache_private = private; 3321 cp->cache_arena = vmp; 3322 cp->cache_cflags = cflags; 3323 3324 /* 3325 * Determine the chunk size. 3326 */ 3327 chunksize = bufsize; 3328 3329 if (align >= KMEM_ALIGN) { 3330 chunksize = P2ROUNDUP(chunksize, KMEM_ALIGN); 3331 cp->cache_bufctl = chunksize - KMEM_ALIGN; 3332 } 3333 3334 if (cp->cache_flags & KMF_BUFTAG) { 3335 cp->cache_bufctl = chunksize; 3336 cp->cache_buftag = chunksize; 3337 if (cp->cache_flags & KMF_LITE) 3338 chunksize += KMEM_BUFTAG_LITE_SIZE(kmem_lite_count); 3339 else 3340 chunksize += sizeof (kmem_buftag_t); 3341 } 3342 3343 if (cp->cache_flags & KMF_DEADBEEF) { 3344 cp->cache_verify = MIN(cp->cache_buftag, kmem_maxverify); 3345 if (cp->cache_flags & KMF_LITE) 3346 cp->cache_verify = sizeof (uint64_t); 3347 } 3348 3349 cp->cache_contents = MIN(cp->cache_bufctl, kmem_content_maxsave); 3350 3351 cp->cache_chunksize = chunksize = P2ROUNDUP(chunksize, align); 3352 3353 /* 3354 * Now that we know the chunk size, determine the optimal slab size. 3355 */ 3356 if (vmp == kmem_firewall_arena) { 3357 cp->cache_slabsize = P2ROUNDUP(chunksize, vmp->vm_quantum); 3358 cp->cache_mincolor = cp->cache_slabsize - chunksize; 3359 cp->cache_maxcolor = cp->cache_mincolor; 3360 cp->cache_flags |= KMF_HASH; 3361 ASSERT(!(cp->cache_flags & KMF_BUFTAG)); 3362 } else if ((cflags & KMC_NOHASH) || (!(cflags & KMC_NOTOUCH) && 3363 !(cp->cache_flags & KMF_AUDIT) && 3364 chunksize < vmp->vm_quantum / KMEM_VOID_FRACTION)) { 3365 cp->cache_slabsize = vmp->vm_quantum; 3366 cp->cache_mincolor = 0; 3367 cp->cache_maxcolor = 3368 (cp->cache_slabsize - sizeof (kmem_slab_t)) % chunksize; 3369 ASSERT(chunksize + sizeof (kmem_slab_t) <= cp->cache_slabsize); 3370 ASSERT(!(cp->cache_flags & KMF_AUDIT)); 3371 } else { 3372 size_t chunks, bestfit, waste, slabsize; 3373 size_t minwaste = LONG_MAX; 3374 3375 for (chunks = 1; chunks <= KMEM_VOID_FRACTION; chunks++) { 3376 slabsize = P2ROUNDUP(chunksize * chunks, 3377 vmp->vm_quantum); 3378 chunks = slabsize / chunksize; 3379 waste = (slabsize % chunksize) / chunks; 3380 if (waste < minwaste) { 3381 minwaste = waste; 3382 bestfit = slabsize; 3383 } 3384 } 3385 if (cflags & KMC_QCACHE) 3386 bestfit = VMEM_QCACHE_SLABSIZE(vmp->vm_qcache_max); 3387 cp->cache_slabsize = bestfit; 3388 cp->cache_mincolor = 0; 3389 cp->cache_maxcolor = bestfit % chunksize; 3390 cp->cache_flags |= KMF_HASH; 3391 } 3392 3393 cp->cache_maxchunks = (cp->cache_slabsize / cp->cache_chunksize); 3394 cp->cache_partial_binshift = highbit(cp->cache_maxchunks / 16) + 1; 3395 3396 if (cp->cache_flags & KMF_HASH) { 3397 ASSERT(!(cflags & KMC_NOHASH)); 3398 cp->cache_bufctl_cache = (cp->cache_flags & KMF_AUDIT) ? 3399 kmem_bufctl_audit_cache : kmem_bufctl_cache; 3400 } 3401 3402 if (cp->cache_maxcolor >= vmp->vm_quantum) 3403 cp->cache_maxcolor = vmp->vm_quantum - 1; 3404 3405 cp->cache_color = cp->cache_mincolor; 3406 3407 /* 3408 * Initialize the rest of the slab layer. 3409 */ 3410 mutex_init(&cp->cache_lock, NULL, MUTEX_DEFAULT, NULL); 3411 3412 avl_create(&cp->cache_partial_slabs, kmem_partial_slab_cmp, 3413 sizeof (kmem_slab_t), offsetof(kmem_slab_t, slab_link)); 3414 /* LINTED: E_TRUE_LOGICAL_EXPR */ 3415 ASSERT(sizeof (list_node_t) <= sizeof (avl_node_t)); 3416 /* reuse partial slab AVL linkage for complete slab list linkage */ 3417 list_create(&cp->cache_complete_slabs, 3418 sizeof (kmem_slab_t), offsetof(kmem_slab_t, slab_link)); 3419 3420 if (cp->cache_flags & KMF_HASH) { 3421 cp->cache_hash_table = vmem_alloc(kmem_hash_arena, 3422 KMEM_HASH_INITIAL * sizeof (void *), VM_SLEEP); 3423 bzero(cp->cache_hash_table, 3424 KMEM_HASH_INITIAL * sizeof (void *)); 3425 cp->cache_hash_mask = KMEM_HASH_INITIAL - 1; 3426 cp->cache_hash_shift = highbit((ulong_t)chunksize) - 1; 3427 } 3428 3429 /* 3430 * Initialize the depot. 3431 */ 3432 mutex_init(&cp->cache_depot_lock, NULL, MUTEX_DEFAULT, NULL); 3433 3434 for (mtp = kmem_magtype; chunksize <= mtp->mt_minbuf; mtp++) 3435 continue; 3436 3437 cp->cache_magtype = mtp; 3438 3439 /* 3440 * Initialize the CPU layer. 3441 */ 3442 for (cpu_seqid = 0; cpu_seqid < max_ncpus; cpu_seqid++) { 3443 kmem_cpu_cache_t *ccp = &cp->cache_cpu[cpu_seqid]; 3444 mutex_init(&ccp->cc_lock, NULL, MUTEX_DEFAULT, NULL); 3445 ccp->cc_flags = cp->cache_flags; 3446 ccp->cc_rounds = -1; 3447 ccp->cc_prounds = -1; 3448 } 3449 3450 /* 3451 * Create the cache's kstats. 3452 */ 3453 if ((cp->cache_kstat = kstat_create("unix", 0, cp->cache_name, 3454 "kmem_cache", KSTAT_TYPE_NAMED, 3455 sizeof (kmem_cache_kstat) / sizeof (kstat_named_t), 3456 KSTAT_FLAG_VIRTUAL)) != NULL) { 3457 cp->cache_kstat->ks_data = &kmem_cache_kstat; 3458 cp->cache_kstat->ks_update = kmem_cache_kstat_update; 3459 cp->cache_kstat->ks_private = cp; 3460 cp->cache_kstat->ks_lock = &kmem_cache_kstat_lock; 3461 kstat_install(cp->cache_kstat); 3462 } 3463 3464 /* 3465 * Add the cache to the global list. This makes it visible 3466 * to kmem_update(), so the cache must be ready for business. 3467 */ 3468 mutex_enter(&kmem_cache_lock); 3469 list_insert_tail(&kmem_caches, cp); 3470 mutex_exit(&kmem_cache_lock); 3471 3472 if (kmem_ready) 3473 kmem_cache_magazine_enable(cp); 3474 3475 if (kmem_move_taskq != NULL && cp->cache_destructor != NULL) { 3476 (void) taskq_dispatch(kmem_move_taskq, 3477 (task_func_t *)kmem_check_destructor, cp, 3478 TQ_NOSLEEP); 3479 } 3480 3481 return (cp); 3482 } 3483 3484 static int 3485 kmem_move_cmp(const void *buf, const void *p) 3486 { 3487 const kmem_move_t *kmm = p; 3488 uintptr_t v1 = (uintptr_t)buf; 3489 uintptr_t v2 = (uintptr_t)kmm->kmm_from_buf; 3490 return (v1 < v2 ? -1 : (v1 > v2 ? 1 : 0)); 3491 } 3492 3493 static void 3494 kmem_reset_reclaim_threshold(kmem_defrag_t *kmd) 3495 { 3496 kmd->kmd_reclaim_numer = 1; 3497 } 3498 3499 /* 3500 * Initially, when choosing candidate slabs for buffers to move, we want to be 3501 * very selective and take only slabs that are less than 3502 * (1 / KMEM_VOID_FRACTION) allocated. If we have difficulty finding candidate 3503 * slabs, then we raise the allocation ceiling incrementally. The reclaim 3504 * threshold is reset to (1 / KMEM_VOID_FRACTION) as soon as the cache is no 3505 * longer fragmented. 3506 */ 3507 static void 3508 kmem_adjust_reclaim_threshold(kmem_defrag_t *kmd, int direction) 3509 { 3510 if (direction > 0) { 3511 /* make it easier to find a candidate slab */ 3512 if (kmd->kmd_reclaim_numer < (KMEM_VOID_FRACTION - 1)) { 3513 kmd->kmd_reclaim_numer++; 3514 } 3515 } else { 3516 /* be more selective */ 3517 if (kmd->kmd_reclaim_numer > 1) { 3518 kmd->kmd_reclaim_numer--; 3519 } 3520 } 3521 } 3522 3523 void 3524 kmem_cache_set_move(kmem_cache_t *cp, 3525 kmem_cbrc_t (*move)(void *, void *, size_t, void *)) 3526 { 3527 kmem_defrag_t *defrag; 3528 3529 ASSERT(move != NULL); 3530 /* 3531 * The consolidator does not support NOTOUCH caches because kmem cannot 3532 * initialize their slabs with the 0xbaddcafe memory pattern, which sets 3533 * a low order bit usable by clients to distinguish uninitialized memory 3534 * from known objects (see kmem_slab_create). 3535 */ 3536 ASSERT(!(cp->cache_cflags & KMC_NOTOUCH)); 3537 ASSERT(!(cp->cache_cflags & KMC_IDENTIFIER)); 3538 3539 /* 3540 * We should not be holding anyone's cache lock when calling 3541 * kmem_cache_alloc(), so allocate in all cases before acquiring the 3542 * lock. 3543 */ 3544 defrag = kmem_cache_alloc(kmem_defrag_cache, KM_SLEEP); 3545 3546 mutex_enter(&cp->cache_lock); 3547 3548 if (KMEM_IS_MOVABLE(cp)) { 3549 if (cp->cache_move == NULL) { 3550 /* 3551 * The client must not have allocated any objects from 3552 * this cache before setting a move callback function. 3553 */ 3554 ASSERT(cp->cache_bufmax == 0); 3555 3556 cp->cache_defrag = defrag; 3557 defrag = NULL; /* nothing to free */ 3558 bzero(cp->cache_defrag, sizeof (kmem_defrag_t)); 3559 avl_create(&cp->cache_defrag->kmd_moves_pending, 3560 kmem_move_cmp, sizeof (kmem_move_t), 3561 offsetof(kmem_move_t, kmm_entry)); 3562 /* LINTED: E_TRUE_LOGICAL_EXPR */ 3563 ASSERT(sizeof (list_node_t) <= sizeof (avl_node_t)); 3564 /* reuse the slab's AVL linkage for deadlist linkage */ 3565 list_create(&cp->cache_defrag->kmd_deadlist, 3566 sizeof (kmem_slab_t), 3567 offsetof(kmem_slab_t, slab_link)); 3568 kmem_reset_reclaim_threshold(cp->cache_defrag); 3569 } 3570 cp->cache_move = move; 3571 } 3572 3573 mutex_exit(&cp->cache_lock); 3574 3575 if (defrag != NULL) { 3576 kmem_cache_free(kmem_defrag_cache, defrag); /* unused */ 3577 } 3578 } 3579 3580 void 3581 kmem_cache_destroy(kmem_cache_t *cp) 3582 { 3583 int cpu_seqid; 3584 3585 /* 3586 * Remove the cache from the global cache list so that no one else 3587 * can schedule tasks on its behalf, wait for any pending tasks to 3588 * complete, purge the cache, and then destroy it. 3589 */ 3590 mutex_enter(&kmem_cache_lock); 3591 list_remove(&kmem_caches, cp); 3592 mutex_exit(&kmem_cache_lock); 3593 3594 if (kmem_taskq != NULL) 3595 taskq_wait(kmem_taskq); 3596 if (kmem_move_taskq != NULL) 3597 taskq_wait(kmem_move_taskq); 3598 3599 kmem_cache_magazine_purge(cp); 3600 3601 mutex_enter(&cp->cache_lock); 3602 if (cp->cache_buftotal != 0) 3603 cmn_err(CE_WARN, "kmem_cache_destroy: '%s' (%p) not empty", 3604 cp->cache_name, (void *)cp); 3605 if (cp->cache_defrag != NULL) { 3606 avl_destroy(&cp->cache_defrag->kmd_moves_pending); 3607 list_destroy(&cp->cache_defrag->kmd_deadlist); 3608 kmem_cache_free(kmem_defrag_cache, cp->cache_defrag); 3609 cp->cache_defrag = NULL; 3610 } 3611 /* 3612 * The cache is now dead. There should be no further activity. We 3613 * enforce this by setting land mines in the constructor, destructor, 3614 * reclaim, and move routines that induce a kernel text fault if 3615 * invoked. 3616 */ 3617 cp->cache_constructor = (int (*)(void *, void *, int))1; 3618 cp->cache_destructor = (void (*)(void *, void *))2; 3619 cp->cache_reclaim = (void (*)(void *))3; 3620 cp->cache_move = (kmem_cbrc_t (*)(void *, void *, size_t, void *))4; 3621 mutex_exit(&cp->cache_lock); 3622 3623 kstat_delete(cp->cache_kstat); 3624 3625 if (cp->cache_hash_table != NULL) 3626 vmem_free(kmem_hash_arena, cp->cache_hash_table, 3627 (cp->cache_hash_mask + 1) * sizeof (void *)); 3628 3629 for (cpu_seqid = 0; cpu_seqid < max_ncpus; cpu_seqid++) 3630 mutex_destroy(&cp->cache_cpu[cpu_seqid].cc_lock); 3631 3632 mutex_destroy(&cp->cache_depot_lock); 3633 mutex_destroy(&cp->cache_lock); 3634 3635 vmem_free(kmem_cache_arena, cp, KMEM_CACHE_SIZE(max_ncpus)); 3636 } 3637 3638 /*ARGSUSED*/ 3639 static int 3640 kmem_cpu_setup(cpu_setup_t what, int id, void *arg) 3641 { 3642 ASSERT(MUTEX_HELD(&cpu_lock)); 3643 if (what == CPU_UNCONFIG) { 3644 kmem_cache_applyall(kmem_cache_magazine_purge, 3645 kmem_taskq, TQ_SLEEP); 3646 kmem_cache_applyall(kmem_cache_magazine_enable, 3647 kmem_taskq, TQ_SLEEP); 3648 } 3649 return (0); 3650 } 3651 3652 static void 3653 kmem_cache_init(int pass, int use_large_pages) 3654 { 3655 int i; 3656 size_t size; 3657 kmem_cache_t *cp; 3658 kmem_magtype_t *mtp; 3659 char name[KMEM_CACHE_NAMELEN + 1]; 3660 3661 for (i = 0; i < sizeof (kmem_magtype) / sizeof (*mtp); i++) { 3662 mtp = &kmem_magtype[i]; 3663 (void) sprintf(name, "kmem_magazine_%d", mtp->mt_magsize); 3664 mtp->mt_cache = kmem_cache_create(name, 3665 (mtp->mt_magsize + 1) * sizeof (void *), 3666 mtp->mt_align, NULL, NULL, NULL, NULL, 3667 kmem_msb_arena, KMC_NOHASH); 3668 } 3669 3670 kmem_slab_cache = kmem_cache_create("kmem_slab_cache", 3671 sizeof (kmem_slab_t), 0, NULL, NULL, NULL, NULL, 3672 kmem_msb_arena, KMC_NOHASH); 3673 3674 kmem_bufctl_cache = kmem_cache_create("kmem_bufctl_cache", 3675 sizeof (kmem_bufctl_t), 0, NULL, NULL, NULL, NULL, 3676 kmem_msb_arena, KMC_NOHASH); 3677 3678 kmem_bufctl_audit_cache = kmem_cache_create("kmem_bufctl_audit_cache", 3679 sizeof (kmem_bufctl_audit_t), 0, NULL, NULL, NULL, NULL, 3680 kmem_msb_arena, KMC_NOHASH); 3681 3682 if (pass == 2) { 3683 kmem_va_arena = vmem_create("kmem_va", 3684 NULL, 0, PAGESIZE, 3685 vmem_alloc, vmem_free, heap_arena, 3686 8 * PAGESIZE, VM_SLEEP); 3687 3688 if (use_large_pages) { 3689 kmem_default_arena = vmem_xcreate("kmem_default", 3690 NULL, 0, PAGESIZE, 3691 segkmem_alloc_lp, segkmem_free_lp, kmem_va_arena, 3692 0, VM_SLEEP); 3693 } else { 3694 kmem_default_arena = vmem_create("kmem_default", 3695 NULL, 0, PAGESIZE, 3696 segkmem_alloc, segkmem_free, kmem_va_arena, 3697 0, VM_SLEEP); 3698 } 3699 } else { 3700 /* 3701 * During the first pass, the kmem_alloc_* caches 3702 * are treated as metadata. 3703 */ 3704 kmem_default_arena = kmem_msb_arena; 3705 } 3706 3707 /* 3708 * Set up the default caches to back kmem_alloc() 3709 */ 3710 size = KMEM_ALIGN; 3711 for (i = 0; i < sizeof (kmem_alloc_sizes) / sizeof (int); i++) { 3712 size_t align = KMEM_ALIGN; 3713 size_t cache_size = kmem_alloc_sizes[i]; 3714 /* 3715 * If they allocate a multiple of the coherency granularity, 3716 * they get a coherency-granularity-aligned address. 3717 */ 3718 if (IS_P2ALIGNED(cache_size, 64)) 3719 align = 64; 3720 if (IS_P2ALIGNED(cache_size, PAGESIZE)) 3721 align = PAGESIZE; 3722 (void) sprintf(name, "kmem_alloc_%lu", cache_size); 3723 cp = kmem_cache_create(name, cache_size, align, 3724 NULL, NULL, NULL, NULL, NULL, KMC_KMEM_ALLOC); 3725 while (size <= cache_size) { 3726 kmem_alloc_table[(size - 1) >> KMEM_ALIGN_SHIFT] = cp; 3727 size += KMEM_ALIGN; 3728 } 3729 } 3730 } 3731 3732 void 3733 kmem_init(void) 3734 { 3735 kmem_cache_t *cp; 3736 int old_kmem_flags = kmem_flags; 3737 int use_large_pages = 0; 3738 size_t maxverify, minfirewall; 3739 3740 kstat_init(); 3741 3742 /* 3743 * Small-memory systems (< 24 MB) can't handle kmem_flags overhead. 3744 */ 3745 if (physmem < btop(24 << 20) && !(old_kmem_flags & KMF_STICKY)) 3746 kmem_flags = 0; 3747 3748 /* 3749 * Don't do firewalled allocations if the heap is less than 1TB 3750 * (i.e. on a 32-bit kernel) 3751 * The resulting VM_NEXTFIT allocations would create too much 3752 * fragmentation in a small heap. 3753 */ 3754 #if defined(_LP64) 3755 maxverify = minfirewall = PAGESIZE / 2; 3756 #else 3757 maxverify = minfirewall = ULONG_MAX; 3758 #endif 3759 3760 /* LINTED */ 3761 ASSERT(sizeof (kmem_cpu_cache_t) == KMEM_CPU_CACHE_SIZE); 3762 3763 list_create(&kmem_caches, sizeof (kmem_cache_t), 3764 offsetof(kmem_cache_t, cache_link)); 3765 3766 kmem_metadata_arena = vmem_create("kmem_metadata", NULL, 0, PAGESIZE, 3767 vmem_alloc, vmem_free, heap_arena, 8 * PAGESIZE, 3768 VM_SLEEP | VMC_NO_QCACHE); 3769 3770 kmem_msb_arena = vmem_create("kmem_msb", NULL, 0, 3771 PAGESIZE, segkmem_alloc, segkmem_free, kmem_metadata_arena, 0, 3772 VM_SLEEP); 3773 3774 kmem_cache_arena = vmem_create("kmem_cache", NULL, 0, KMEM_ALIGN, 3775 segkmem_alloc, segkmem_free, kmem_metadata_arena, 0, VM_SLEEP); 3776 3777 kmem_hash_arena = vmem_create("kmem_hash", NULL, 0, KMEM_ALIGN, 3778 segkmem_alloc, segkmem_free, kmem_metadata_arena, 0, VM_SLEEP); 3779 3780 kmem_log_arena = vmem_create("kmem_log", NULL, 0, KMEM_ALIGN, 3781 segkmem_alloc, segkmem_free, heap_arena, 0, VM_SLEEP); 3782 3783 kmem_firewall_va_arena = vmem_create("kmem_firewall_va", 3784 NULL, 0, PAGESIZE, 3785 kmem_firewall_va_alloc, kmem_firewall_va_free, heap_arena, 3786 0, VM_SLEEP); 3787 3788 kmem_firewall_arena = vmem_create("kmem_firewall", NULL, 0, PAGESIZE, 3789 segkmem_alloc, segkmem_free, kmem_firewall_va_arena, 0, VM_SLEEP); 3790 3791 /* temporary oversize arena for mod_read_system_file */ 3792 kmem_oversize_arena = vmem_create("kmem_oversize", NULL, 0, PAGESIZE, 3793 segkmem_alloc, segkmem_free, heap_arena, 0, VM_SLEEP); 3794 3795 kmem_reap_interval = 15 * hz; 3796 3797 /* 3798 * Read /etc/system. This is a chicken-and-egg problem because 3799 * kmem_flags may be set in /etc/system, but mod_read_system_file() 3800 * needs to use the allocator. The simplest solution is to create 3801 * all the standard kmem caches, read /etc/system, destroy all the 3802 * caches we just created, and then create them all again in light 3803 * of the (possibly) new kmem_flags and other kmem tunables. 3804 */ 3805 kmem_cache_init(1, 0); 3806 3807 mod_read_system_file(boothowto & RB_ASKNAME); 3808 3809 while ((cp = list_tail(&kmem_caches)) != NULL) 3810 kmem_cache_destroy(cp); 3811 3812 vmem_destroy(kmem_oversize_arena); 3813 3814 if (old_kmem_flags & KMF_STICKY) 3815 kmem_flags = old_kmem_flags; 3816 3817 if (!(kmem_flags & KMF_AUDIT)) 3818 vmem_seg_size = offsetof(vmem_seg_t, vs_thread); 3819 3820 if (kmem_maxverify == 0) 3821 kmem_maxverify = maxverify; 3822 3823 if (kmem_minfirewall == 0) 3824 kmem_minfirewall = minfirewall; 3825 3826 /* 3827 * give segkmem a chance to figure out if we are using large pages 3828 * for the kernel heap 3829 */ 3830 use_large_pages = segkmem_lpsetup(); 3831 3832 /* 3833 * To protect against corruption, we keep the actual number of callers 3834 * KMF_LITE records seperate from the tunable. We arbitrarily clamp 3835 * to 16, since the overhead for small buffers quickly gets out of 3836 * hand. 3837 * 3838 * The real limit would depend on the needs of the largest KMC_NOHASH 3839 * cache. 3840 */ 3841 kmem_lite_count = MIN(MAX(0, kmem_lite_pcs), 16); 3842 kmem_lite_pcs = kmem_lite_count; 3843 3844 /* 3845 * Normally, we firewall oversized allocations when possible, but 3846 * if we are using large pages for kernel memory, and we don't have 3847 * any non-LITE debugging flags set, we want to allocate oversized 3848 * buffers from large pages, and so skip the firewalling. 3849 */ 3850 if (use_large_pages && 3851 ((kmem_flags & KMF_LITE) || !(kmem_flags & KMF_DEBUG))) { 3852 kmem_oversize_arena = vmem_xcreate("kmem_oversize", NULL, 0, 3853 PAGESIZE, segkmem_alloc_lp, segkmem_free_lp, heap_arena, 3854 0, VM_SLEEP); 3855 } else { 3856 kmem_oversize_arena = vmem_create("kmem_oversize", 3857 NULL, 0, PAGESIZE, 3858 segkmem_alloc, segkmem_free, kmem_minfirewall < ULONG_MAX? 3859 kmem_firewall_va_arena : heap_arena, 0, VM_SLEEP); 3860 } 3861 3862 kmem_cache_init(2, use_large_pages); 3863 3864 if (kmem_flags & (KMF_AUDIT | KMF_RANDOMIZE)) { 3865 if (kmem_transaction_log_size == 0) 3866 kmem_transaction_log_size = kmem_maxavail() / 50; 3867 kmem_transaction_log = kmem_log_init(kmem_transaction_log_size); 3868 } 3869 3870 if (kmem_flags & (KMF_CONTENTS | KMF_RANDOMIZE)) { 3871 if (kmem_content_log_size == 0) 3872 kmem_content_log_size = kmem_maxavail() / 50; 3873 kmem_content_log = kmem_log_init(kmem_content_log_size); 3874 } 3875 3876 kmem_failure_log = kmem_log_init(kmem_failure_log_size); 3877 3878 kmem_slab_log = kmem_log_init(kmem_slab_log_size); 3879 3880 /* 3881 * Initialize STREAMS message caches so allocb() is available. 3882 * This allows us to initialize the logging framework (cmn_err(9F), 3883 * strlog(9F), etc) so we can start recording messages. 3884 */ 3885 streams_msg_init(); 3886 3887 /* 3888 * Initialize the ZSD framework in Zones so modules loaded henceforth 3889 * can register their callbacks. 3890 */ 3891 zone_zsd_init(); 3892 3893 log_init(); 3894 taskq_init(); 3895 3896 /* 3897 * Warn about invalid or dangerous values of kmem_flags. 3898 * Always warn about unsupported values. 3899 */ 3900 if (((kmem_flags & ~(KMF_AUDIT | KMF_DEADBEEF | KMF_REDZONE | 3901 KMF_CONTENTS | KMF_LITE)) != 0) || 3902 ((kmem_flags & KMF_LITE) && kmem_flags != KMF_LITE)) 3903 cmn_err(CE_WARN, "kmem_flags set to unsupported value 0x%x. " 3904 "See the Solaris Tunable Parameters Reference Manual.", 3905 kmem_flags); 3906 3907 #ifdef DEBUG 3908 if ((kmem_flags & KMF_DEBUG) == 0) 3909 cmn_err(CE_NOTE, "kmem debugging disabled."); 3910 #else 3911 /* 3912 * For non-debug kernels, the only "normal" flags are 0, KMF_LITE, 3913 * KMF_REDZONE, and KMF_CONTENTS (the last because it is only enabled 3914 * if KMF_AUDIT is set). We should warn the user about the performance 3915 * penalty of KMF_AUDIT or KMF_DEADBEEF if they are set and KMF_LITE 3916 * isn't set (since that disables AUDIT). 3917 */ 3918 if (!(kmem_flags & KMF_LITE) && 3919 (kmem_flags & (KMF_AUDIT | KMF_DEADBEEF)) != 0) 3920 cmn_err(CE_WARN, "High-overhead kmem debugging features " 3921 "enabled (kmem_flags = 0x%x). Performance degradation " 3922 "and large memory overhead possible. See the Solaris " 3923 "Tunable Parameters Reference Manual.", kmem_flags); 3924 #endif /* not DEBUG */ 3925 3926 kmem_cache_applyall(kmem_cache_magazine_enable, NULL, TQ_SLEEP); 3927 3928 kmem_ready = 1; 3929 3930 /* 3931 * Initialize the platform-specific aligned/DMA memory allocator. 3932 */ 3933 ka_init(); 3934 3935 /* 3936 * Initialize 32-bit ID cache. 3937 */ 3938 id32_init(); 3939 3940 /* 3941 * Initialize the networking stack so modules loaded can 3942 * register their callbacks. 3943 */ 3944 netstack_init(); 3945 } 3946 3947 static void 3948 kmem_move_init(void) 3949 { 3950 kmem_defrag_cache = kmem_cache_create("kmem_defrag_cache", 3951 sizeof (kmem_defrag_t), 0, NULL, NULL, NULL, NULL, 3952 kmem_msb_arena, KMC_NOHASH); 3953 kmem_move_cache = kmem_cache_create("kmem_move_cache", 3954 sizeof (kmem_move_t), 0, NULL, NULL, NULL, NULL, 3955 kmem_msb_arena, KMC_NOHASH); 3956 3957 /* 3958 * kmem guarantees that move callbacks are sequential and that even 3959 * across multiple caches no two moves ever execute simultaneously. 3960 * Move callbacks are processed on a separate taskq so that client code 3961 * does not interfere with internal maintenance tasks. 3962 */ 3963 kmem_move_taskq = taskq_create_instance("kmem_move_taskq", 0, 1, 3964 minclsyspri, 100, INT_MAX, TASKQ_PREPOPULATE); 3965 } 3966 3967 void 3968 kmem_thread_init(void) 3969 { 3970 kmem_move_init(); 3971 kmem_taskq = taskq_create_instance("kmem_taskq", 0, 1, minclsyspri, 3972 300, INT_MAX, TASKQ_PREPOPULATE); 3973 kmem_cache_applyall(kmem_check_destructor, kmem_move_taskq, 3974 TQ_NOSLEEP); 3975 } 3976 3977 void 3978 kmem_mp_init(void) 3979 { 3980 mutex_enter(&cpu_lock); 3981 register_cpu_setup_func(kmem_cpu_setup, NULL); 3982 mutex_exit(&cpu_lock); 3983 3984 kmem_update_timeout(NULL); 3985 } 3986 3987 /* 3988 * Return the slab of the allocated buffer, or NULL if the buffer is not 3989 * allocated. This function may be called with a known slab address to determine 3990 * whether or not the buffer is allocated, or with a NULL slab address to obtain 3991 * an allocated buffer's slab. 3992 */ 3993 static kmem_slab_t * 3994 kmem_slab_allocated(kmem_cache_t *cp, kmem_slab_t *sp, void *buf) 3995 { 3996 kmem_bufctl_t *bcp, *bufbcp; 3997 3998 ASSERT(MUTEX_HELD(&cp->cache_lock)); 3999 ASSERT(sp == NULL || KMEM_SLAB_MEMBER(sp, buf)); 4000 4001 if (cp->cache_flags & KMF_HASH) { 4002 for (bcp = *KMEM_HASH(cp, buf); 4003 (bcp != NULL) && (bcp->bc_addr != buf); 4004 bcp = bcp->bc_next) { 4005 continue; 4006 } 4007 ASSERT(sp != NULL && bcp != NULL ? sp == bcp->bc_slab : 1); 4008 return (bcp == NULL ? NULL : bcp->bc_slab); 4009 } 4010 4011 if (sp == NULL) { 4012 sp = KMEM_SLAB(cp, buf); 4013 } 4014 bufbcp = KMEM_BUFCTL(cp, buf); 4015 for (bcp = sp->slab_head; 4016 (bcp != NULL) && (bcp != bufbcp); 4017 bcp = bcp->bc_next) { 4018 continue; 4019 } 4020 return (bcp == NULL ? sp : NULL); 4021 } 4022 4023 static boolean_t 4024 kmem_slab_is_reclaimable(kmem_cache_t *cp, kmem_slab_t *sp, int flags) 4025 { 4026 long refcnt; 4027 4028 ASSERT(cp->cache_defrag != NULL); 4029 4030 /* If we're desperate, we don't care if the client said NO. */ 4031 refcnt = sp->slab_refcnt; 4032 if (flags & KMM_DESPERATE) { 4033 return (refcnt < sp->slab_chunks); /* any partial */ 4034 } 4035 4036 if (sp->slab_flags & KMEM_SLAB_NOMOVE) { 4037 return (B_FALSE); 4038 } 4039 4040 if (kmem_move_any_partial) { 4041 return (refcnt < sp->slab_chunks); 4042 } 4043 4044 if ((refcnt == 1) && (refcnt < sp->slab_chunks)) { 4045 return (B_TRUE); 4046 } 4047 4048 /* 4049 * The reclaim threshold is adjusted at each kmem_cache_scan() so that 4050 * slabs with a progressively higher percentage of used buffers can be 4051 * reclaimed until the cache as a whole is no longer fragmented. 4052 * 4053 * sp->slab_refcnt kmd_reclaim_numer 4054 * --------------- < ------------------ 4055 * sp->slab_chunks KMEM_VOID_FRACTION 4056 */ 4057 return ((refcnt * KMEM_VOID_FRACTION) < 4058 (sp->slab_chunks * cp->cache_defrag->kmd_reclaim_numer)); 4059 } 4060 4061 static void * 4062 kmem_hunt_mag(kmem_cache_t *cp, kmem_magazine_t *m, int n, void *buf, 4063 void *tbuf) 4064 { 4065 int i; /* magazine round index */ 4066 4067 for (i = 0; i < n; i++) { 4068 if (buf == m->mag_round[i]) { 4069 if (cp->cache_flags & KMF_BUFTAG) { 4070 (void) kmem_cache_free_debug(cp, tbuf, 4071 caller()); 4072 } 4073 m->mag_round[i] = tbuf; 4074 return (buf); 4075 } 4076 } 4077 4078 return (NULL); 4079 } 4080 4081 /* 4082 * Hunt the magazine layer for the given buffer. If found, the buffer is 4083 * removed from the magazine layer and returned, otherwise NULL is returned. 4084 * The state of the returned buffer is freed and constructed. 4085 */ 4086 static void * 4087 kmem_hunt_mags(kmem_cache_t *cp, void *buf) 4088 { 4089 kmem_cpu_cache_t *ccp; 4090 kmem_magazine_t *m; 4091 int cpu_seqid; 4092 int n; /* magazine rounds */ 4093 void *tbuf; /* temporary swap buffer */ 4094 4095 ASSERT(MUTEX_NOT_HELD(&cp->cache_lock)); 4096 4097 /* 4098 * Allocated a buffer to swap with the one we hope to pull out of a 4099 * magazine when found. 4100 */ 4101 tbuf = kmem_cache_alloc(cp, KM_NOSLEEP); 4102 if (tbuf == NULL) { 4103 KMEM_STAT_ADD(kmem_move_stats.kms_hunt_alloc_fail); 4104 return (NULL); 4105 } 4106 if (tbuf == buf) { 4107 KMEM_STAT_ADD(kmem_move_stats.kms_hunt_lucky); 4108 if (cp->cache_flags & KMF_BUFTAG) { 4109 (void) kmem_cache_free_debug(cp, buf, caller()); 4110 } 4111 return (buf); 4112 } 4113 4114 /* Hunt the depot. */ 4115 mutex_enter(&cp->cache_depot_lock); 4116 n = cp->cache_magtype->mt_magsize; 4117 for (m = cp->cache_full.ml_list; m != NULL; m = m->mag_next) { 4118 if (kmem_hunt_mag(cp, m, n, buf, tbuf) != NULL) { 4119 mutex_exit(&cp->cache_depot_lock); 4120 return (buf); 4121 } 4122 } 4123 mutex_exit(&cp->cache_depot_lock); 4124 4125 /* Hunt the per-CPU magazines. */ 4126 for (cpu_seqid = 0; cpu_seqid < max_ncpus; cpu_seqid++) { 4127 ccp = &cp->cache_cpu[cpu_seqid]; 4128 4129 mutex_enter(&ccp->cc_lock); 4130 m = ccp->cc_loaded; 4131 n = ccp->cc_rounds; 4132 if (kmem_hunt_mag(cp, m, n, buf, tbuf) != NULL) { 4133 mutex_exit(&ccp->cc_lock); 4134 return (buf); 4135 } 4136 m = ccp->cc_ploaded; 4137 n = ccp->cc_prounds; 4138 if (kmem_hunt_mag(cp, m, n, buf, tbuf) != NULL) { 4139 mutex_exit(&ccp->cc_lock); 4140 return (buf); 4141 } 4142 mutex_exit(&ccp->cc_lock); 4143 } 4144 4145 kmem_cache_free(cp, tbuf); 4146 return (NULL); 4147 } 4148 4149 /* 4150 * May be called from the kmem_move_taskq, from kmem_cache_move_notify_task(), 4151 * or when the buffer is freed. 4152 */ 4153 static void 4154 kmem_slab_move_yes(kmem_cache_t *cp, kmem_slab_t *sp, void *from_buf) 4155 { 4156 ASSERT(MUTEX_HELD(&cp->cache_lock)); 4157 ASSERT(KMEM_SLAB_MEMBER(sp, from_buf)); 4158 4159 if (!KMEM_SLAB_IS_PARTIAL(sp)) { 4160 return; 4161 } 4162 4163 if (sp->slab_flags & KMEM_SLAB_NOMOVE) { 4164 if (KMEM_SLAB_OFFSET(sp, from_buf) == sp->slab_stuck_offset) { 4165 avl_remove(&cp->cache_partial_slabs, sp); 4166 sp->slab_flags &= ~KMEM_SLAB_NOMOVE; 4167 sp->slab_stuck_offset = (uint32_t)-1; 4168 avl_add(&cp->cache_partial_slabs, sp); 4169 } 4170 } else { 4171 sp->slab_later_count = 0; 4172 sp->slab_stuck_offset = (uint32_t)-1; 4173 } 4174 } 4175 4176 static void 4177 kmem_slab_move_no(kmem_cache_t *cp, kmem_slab_t *sp, void *from_buf) 4178 { 4179 ASSERT(taskq_member(kmem_move_taskq, curthread)); 4180 ASSERT(MUTEX_HELD(&cp->cache_lock)); 4181 ASSERT(KMEM_SLAB_MEMBER(sp, from_buf)); 4182 4183 if (!KMEM_SLAB_IS_PARTIAL(sp)) { 4184 return; 4185 } 4186 4187 avl_remove(&cp->cache_partial_slabs, sp); 4188 sp->slab_later_count = 0; 4189 sp->slab_flags |= KMEM_SLAB_NOMOVE; 4190 sp->slab_stuck_offset = KMEM_SLAB_OFFSET(sp, from_buf); 4191 avl_add(&cp->cache_partial_slabs, sp); 4192 } 4193 4194 static void kmem_move_end(kmem_cache_t *, kmem_move_t *); 4195 4196 /* 4197 * The move callback takes two buffer addresses, the buffer to be moved, and a 4198 * newly allocated and constructed buffer selected by kmem as the destination. 4199 * It also takes the size of the buffer and an optional user argument specified 4200 * at cache creation time. kmem guarantees that the buffer to be moved has not 4201 * been unmapped by the virtual memory subsystem. Beyond that, it cannot 4202 * guarantee the present whereabouts of the buffer to be moved, so it is up to 4203 * the client to safely determine whether or not it is still using the buffer. 4204 * The client must not free either of the buffers passed to the move callback, 4205 * since kmem wants to free them directly to the slab layer. The client response 4206 * tells kmem which of the two buffers to free: 4207 * 4208 * YES kmem frees the old buffer (the move was successful) 4209 * NO kmem frees the new buffer, marks the slab of the old buffer 4210 * non-reclaimable to avoid bothering the client again 4211 * LATER kmem frees the new buffer, increments slab_later_count 4212 * DONT_KNOW kmem frees the new buffer, searches mags for the old buffer 4213 * DONT_NEED kmem frees both the old buffer and the new buffer 4214 * 4215 * The pending callback argument now being processed contains both of the 4216 * buffers (old and new) passed to the move callback function, the slab of the 4217 * old buffer, and flags related to the move request, such as whether or not the 4218 * system was desperate for memory. 4219 */ 4220 static void 4221 kmem_move_buffer(kmem_move_t *callback) 4222 { 4223 kmem_cbrc_t response; 4224 kmem_slab_t *sp = callback->kmm_from_slab; 4225 kmem_cache_t *cp = sp->slab_cache; 4226 boolean_t free_on_slab; 4227 4228 ASSERT(taskq_member(kmem_move_taskq, curthread)); 4229 ASSERT(MUTEX_NOT_HELD(&cp->cache_lock)); 4230 ASSERT(KMEM_SLAB_MEMBER(sp, callback->kmm_from_buf)); 4231 4232 /* 4233 * The number of allocated buffers on the slab may have changed since we 4234 * last checked the slab's reclaimability (when the pending move was 4235 * enqueued), or the client may have responded NO when asked to move 4236 * another buffer on the same slab. 4237 */ 4238 if (!kmem_slab_is_reclaimable(cp, sp, callback->kmm_flags)) { 4239 KMEM_STAT_ADD(kmem_move_stats.kms_no_longer_reclaimable); 4240 KMEM_STAT_COND_ADD((callback->kmm_flags & KMM_NOTIFY), 4241 kmem_move_stats.kms_notify_no_longer_reclaimable); 4242 kmem_slab_free(cp, callback->kmm_to_buf); 4243 kmem_move_end(cp, callback); 4244 return; 4245 } 4246 4247 /* 4248 * Hunting magazines is expensive, so we'll wait to do that until the 4249 * client responds KMEM_CBRC_DONT_KNOW. However, checking the slab layer 4250 * is cheap, so we might as well do that here in case we can avoid 4251 * bothering the client. 4252 */ 4253 mutex_enter(&cp->cache_lock); 4254 free_on_slab = (kmem_slab_allocated(cp, sp, 4255 callback->kmm_from_buf) == NULL); 4256 mutex_exit(&cp->cache_lock); 4257 4258 if (free_on_slab) { 4259 KMEM_STAT_ADD(kmem_move_stats.kms_hunt_found_slab); 4260 kmem_slab_free(cp, callback->kmm_to_buf); 4261 kmem_move_end(cp, callback); 4262 return; 4263 } 4264 4265 if (cp->cache_flags & KMF_BUFTAG) { 4266 /* 4267 * Make kmem_cache_alloc_debug() apply the constructor for us. 4268 */ 4269 if (kmem_cache_alloc_debug(cp, callback->kmm_to_buf, 4270 KM_NOSLEEP, 1, caller()) != 0) { 4271 KMEM_STAT_ADD(kmem_move_stats.kms_alloc_fail); 4272 kmem_move_end(cp, callback); 4273 return; 4274 } 4275 } else if (cp->cache_constructor != NULL && 4276 cp->cache_constructor(callback->kmm_to_buf, cp->cache_private, 4277 KM_NOSLEEP) != 0) { 4278 atomic_add_64(&cp->cache_alloc_fail, 1); 4279 KMEM_STAT_ADD(kmem_move_stats.kms_constructor_fail); 4280 kmem_slab_free(cp, callback->kmm_to_buf); 4281 kmem_move_end(cp, callback); 4282 return; 4283 } 4284 4285 KMEM_STAT_ADD(kmem_move_stats.kms_callbacks); 4286 KMEM_STAT_COND_ADD((callback->kmm_flags & KMM_NOTIFY), 4287 kmem_move_stats.kms_notify_callbacks); 4288 cp->cache_defrag->kmd_callbacks++; 4289 cp->cache_defrag->kmd_thread = curthread; 4290 cp->cache_defrag->kmd_from_buf = callback->kmm_from_buf; 4291 cp->cache_defrag->kmd_to_buf = callback->kmm_to_buf; 4292 DTRACE_PROBE2(kmem__move__start, kmem_cache_t *, cp, kmem_move_t *, 4293 callback); 4294 4295 response = cp->cache_move(callback->kmm_from_buf, 4296 callback->kmm_to_buf, cp->cache_bufsize, cp->cache_private); 4297 4298 DTRACE_PROBE3(kmem__move__end, kmem_cache_t *, cp, kmem_move_t *, 4299 callback, kmem_cbrc_t, response); 4300 cp->cache_defrag->kmd_thread = NULL; 4301 cp->cache_defrag->kmd_from_buf = NULL; 4302 cp->cache_defrag->kmd_to_buf = NULL; 4303 4304 if (response == KMEM_CBRC_YES) { 4305 KMEM_STAT_ADD(kmem_move_stats.kms_yes); 4306 cp->cache_defrag->kmd_yes++; 4307 kmem_slab_free_constructed(cp, callback->kmm_from_buf, B_FALSE); 4308 mutex_enter(&cp->cache_lock); 4309 kmem_slab_move_yes(cp, sp, callback->kmm_from_buf); 4310 mutex_exit(&cp->cache_lock); 4311 kmem_move_end(cp, callback); 4312 return; 4313 } 4314 4315 switch (response) { 4316 case KMEM_CBRC_NO: 4317 KMEM_STAT_ADD(kmem_move_stats.kms_no); 4318 cp->cache_defrag->kmd_no++; 4319 mutex_enter(&cp->cache_lock); 4320 kmem_slab_move_no(cp, sp, callback->kmm_from_buf); 4321 mutex_exit(&cp->cache_lock); 4322 break; 4323 case KMEM_CBRC_LATER: 4324 KMEM_STAT_ADD(kmem_move_stats.kms_later); 4325 cp->cache_defrag->kmd_later++; 4326 mutex_enter(&cp->cache_lock); 4327 if (!KMEM_SLAB_IS_PARTIAL(sp)) { 4328 mutex_exit(&cp->cache_lock); 4329 break; 4330 } 4331 4332 if (++sp->slab_later_count >= KMEM_DISBELIEF) { 4333 KMEM_STAT_ADD(kmem_move_stats.kms_disbelief); 4334 kmem_slab_move_no(cp, sp, callback->kmm_from_buf); 4335 } else if (!(sp->slab_flags & KMEM_SLAB_NOMOVE)) { 4336 sp->slab_stuck_offset = KMEM_SLAB_OFFSET(sp, 4337 callback->kmm_from_buf); 4338 } 4339 mutex_exit(&cp->cache_lock); 4340 break; 4341 case KMEM_CBRC_DONT_NEED: 4342 KMEM_STAT_ADD(kmem_move_stats.kms_dont_need); 4343 cp->cache_defrag->kmd_dont_need++; 4344 kmem_slab_free_constructed(cp, callback->kmm_from_buf, B_FALSE); 4345 mutex_enter(&cp->cache_lock); 4346 kmem_slab_move_yes(cp, sp, callback->kmm_from_buf); 4347 mutex_exit(&cp->cache_lock); 4348 break; 4349 case KMEM_CBRC_DONT_KNOW: 4350 KMEM_STAT_ADD(kmem_move_stats.kms_dont_know); 4351 cp->cache_defrag->kmd_dont_know++; 4352 if (kmem_hunt_mags(cp, callback->kmm_from_buf) != NULL) { 4353 KMEM_STAT_ADD(kmem_move_stats.kms_hunt_found_mag); 4354 cp->cache_defrag->kmd_hunt_found++; 4355 kmem_slab_free_constructed(cp, callback->kmm_from_buf, 4356 B_TRUE); 4357 mutex_enter(&cp->cache_lock); 4358 kmem_slab_move_yes(cp, sp, callback->kmm_from_buf); 4359 mutex_exit(&cp->cache_lock); 4360 } else { 4361 KMEM_STAT_ADD(kmem_move_stats.kms_hunt_notfound); 4362 } 4363 break; 4364 default: 4365 panic("'%s' (%p) unexpected move callback response %d\n", 4366 cp->cache_name, (void *)cp, response); 4367 } 4368 4369 kmem_slab_free_constructed(cp, callback->kmm_to_buf, B_FALSE); 4370 kmem_move_end(cp, callback); 4371 } 4372 4373 /* Return B_FALSE if there is insufficient memory for the move request. */ 4374 static boolean_t 4375 kmem_move_begin(kmem_cache_t *cp, kmem_slab_t *sp, void *buf, int flags) 4376 { 4377 void *to_buf; 4378 avl_index_t index; 4379 kmem_move_t *callback, *pending; 4380 4381 ASSERT(taskq_member(kmem_taskq, curthread)); 4382 ASSERT(MUTEX_NOT_HELD(&cp->cache_lock)); 4383 ASSERT(sp->slab_flags & KMEM_SLAB_MOVE_PENDING); 4384 4385 callback = kmem_cache_alloc(kmem_move_cache, KM_NOSLEEP); 4386 if (callback == NULL) { 4387 KMEM_STAT_ADD(kmem_move_stats.kms_callback_alloc_fail); 4388 return (B_FALSE); 4389 } 4390 4391 callback->kmm_from_slab = sp; 4392 callback->kmm_from_buf = buf; 4393 callback->kmm_flags = flags; 4394 4395 mutex_enter(&cp->cache_lock); 4396 4397 if (avl_numnodes(&cp->cache_partial_slabs) <= 1) { 4398 mutex_exit(&cp->cache_lock); 4399 kmem_cache_free(kmem_move_cache, callback); 4400 return (B_TRUE); /* there is no need for the move request */ 4401 } 4402 4403 pending = avl_find(&cp->cache_defrag->kmd_moves_pending, buf, &index); 4404 if (pending != NULL) { 4405 /* 4406 * If the move is already pending and we're desperate now, 4407 * update the move flags. 4408 */ 4409 if (flags & KMM_DESPERATE) { 4410 pending->kmm_flags |= KMM_DESPERATE; 4411 } 4412 mutex_exit(&cp->cache_lock); 4413 KMEM_STAT_ADD(kmem_move_stats.kms_already_pending); 4414 kmem_cache_free(kmem_move_cache, callback); 4415 return (B_TRUE); 4416 } 4417 4418 to_buf = kmem_slab_alloc_impl(cp, avl_first(&cp->cache_partial_slabs)); 4419 callback->kmm_to_buf = to_buf; 4420 avl_insert(&cp->cache_defrag->kmd_moves_pending, callback, index); 4421 4422 mutex_exit(&cp->cache_lock); 4423 4424 if (!taskq_dispatch(kmem_move_taskq, (task_func_t *)kmem_move_buffer, 4425 callback, TQ_NOSLEEP)) { 4426 mutex_enter(&cp->cache_lock); 4427 avl_remove(&cp->cache_defrag->kmd_moves_pending, callback); 4428 mutex_exit(&cp->cache_lock); 4429 kmem_slab_free_constructed(cp, to_buf, B_FALSE); 4430 kmem_cache_free(kmem_move_cache, callback); 4431 return (B_FALSE); 4432 } 4433 4434 return (B_TRUE); 4435 } 4436 4437 static void 4438 kmem_move_end(kmem_cache_t *cp, kmem_move_t *callback) 4439 { 4440 avl_index_t index; 4441 4442 ASSERT(cp->cache_defrag != NULL); 4443 ASSERT(taskq_member(kmem_move_taskq, curthread)); 4444 ASSERT(MUTEX_NOT_HELD(&cp->cache_lock)); 4445 4446 mutex_enter(&cp->cache_lock); 4447 VERIFY(avl_find(&cp->cache_defrag->kmd_moves_pending, 4448 callback->kmm_from_buf, &index) != NULL); 4449 avl_remove(&cp->cache_defrag->kmd_moves_pending, callback); 4450 if (avl_is_empty(&cp->cache_defrag->kmd_moves_pending)) { 4451 list_t *deadlist = &cp->cache_defrag->kmd_deadlist; 4452 kmem_slab_t *sp; 4453 4454 /* 4455 * The last pending move completed. Release all slabs from the 4456 * front of the dead list except for any slab at the tail that 4457 * needs to be released from the context of kmem_move_buffers(). 4458 * kmem deferred unmapping the buffers on these slabs in order 4459 * to guarantee that buffers passed to the move callback have 4460 * been touched only by kmem or by the client itself. 4461 */ 4462 while ((sp = list_remove_head(deadlist)) != NULL) { 4463 if (sp->slab_flags & KMEM_SLAB_MOVE_PENDING) { 4464 list_insert_tail(deadlist, sp); 4465 break; 4466 } 4467 cp->cache_defrag->kmd_deadcount--; 4468 cp->cache_slab_destroy++; 4469 mutex_exit(&cp->cache_lock); 4470 kmem_slab_destroy(cp, sp); 4471 KMEM_STAT_ADD(kmem_move_stats.kms_dead_slabs_freed); 4472 mutex_enter(&cp->cache_lock); 4473 } 4474 } 4475 mutex_exit(&cp->cache_lock); 4476 kmem_cache_free(kmem_move_cache, callback); 4477 } 4478 4479 /* 4480 * Move buffers from least used slabs first by scanning backwards from the end 4481 * of the partial slab list. Scan at most max_scan candidate slabs and move 4482 * buffers from at most max_slabs slabs (0 for all partial slabs in both cases). 4483 * If desperate to reclaim memory, move buffers from any partial slab, otherwise 4484 * skip slabs with a ratio of allocated buffers at or above the current 4485 * threshold. Return the number of unskipped slabs (at most max_slabs, -1 if the 4486 * scan is aborted) so that the caller can adjust the reclaimability threshold 4487 * depending on how many reclaimable slabs it finds. 4488 * 4489 * kmem_move_buffers() drops and reacquires cache_lock every time it issues a 4490 * move request, since it is not valid for kmem_move_begin() to call 4491 * kmem_cache_alloc() or taskq_dispatch() with cache_lock held. 4492 */ 4493 static int 4494 kmem_move_buffers(kmem_cache_t *cp, size_t max_scan, size_t max_slabs, 4495 int flags) 4496 { 4497 kmem_slab_t *sp; 4498 void *buf; 4499 int i, j; /* slab index, buffer index */ 4500 int s; /* reclaimable slabs */ 4501 int b; /* allocated (movable) buffers on reclaimable slab */ 4502 boolean_t success; 4503 int refcnt; 4504 int nomove; 4505 4506 ASSERT(taskq_member(kmem_taskq, curthread)); 4507 ASSERT(MUTEX_HELD(&cp->cache_lock)); 4508 ASSERT(kmem_move_cache != NULL); 4509 ASSERT(cp->cache_move != NULL && cp->cache_defrag != NULL); 4510 ASSERT(avl_numnodes(&cp->cache_partial_slabs) > 1); 4511 4512 if (kmem_move_blocked) { 4513 return (0); 4514 } 4515 4516 if (kmem_move_fulltilt) { 4517 max_slabs = 0; 4518 flags |= KMM_DESPERATE; 4519 } 4520 4521 if (max_scan == 0 || (flags & KMM_DESPERATE)) { 4522 /* 4523 * Scan as many slabs as needed to find the desired number of 4524 * candidate slabs. 4525 */ 4526 max_scan = (size_t)-1; 4527 } 4528 4529 if (max_slabs == 0 || (flags & KMM_DESPERATE)) { 4530 /* Find as many candidate slabs as possible. */ 4531 max_slabs = (size_t)-1; 4532 } 4533 4534 sp = avl_last(&cp->cache_partial_slabs); 4535 ASSERT(sp != NULL && KMEM_SLAB_IS_PARTIAL(sp)); 4536 for (i = 0, s = 0; (i < max_scan) && (s < max_slabs) && 4537 (sp != avl_first(&cp->cache_partial_slabs)); 4538 sp = AVL_PREV(&cp->cache_partial_slabs, sp), i++) { 4539 4540 if (!kmem_slab_is_reclaimable(cp, sp, flags)) { 4541 continue; 4542 } 4543 s++; 4544 4545 /* Look for allocated buffers to move. */ 4546 for (j = 0, b = 0, buf = sp->slab_base; 4547 (j < sp->slab_chunks) && (b < sp->slab_refcnt); 4548 buf = (((char *)buf) + cp->cache_chunksize), j++) { 4549 4550 if (kmem_slab_allocated(cp, sp, buf) == NULL) { 4551 continue; 4552 } 4553 4554 b++; 4555 4556 /* 4557 * Prevent the slab from being destroyed while we drop 4558 * cache_lock and while the pending move is not yet 4559 * registered. Flag the pending move while 4560 * kmd_moves_pending may still be empty, since we can't 4561 * yet rely on a non-zero pending move count to prevent 4562 * the slab from being destroyed. 4563 */ 4564 ASSERT(!(sp->slab_flags & KMEM_SLAB_MOVE_PENDING)); 4565 sp->slab_flags |= KMEM_SLAB_MOVE_PENDING; 4566 /* 4567 * Recheck refcnt and nomove after reacquiring the lock, 4568 * since these control the order of partial slabs, and 4569 * we want to know if we can pick up the scan where we 4570 * left off. 4571 */ 4572 refcnt = sp->slab_refcnt; 4573 nomove = (sp->slab_flags & KMEM_SLAB_NOMOVE); 4574 mutex_exit(&cp->cache_lock); 4575 4576 success = kmem_move_begin(cp, sp, buf, flags); 4577 4578 /* 4579 * Now, before the lock is reacquired, kmem could 4580 * process all pending move requests and purge the 4581 * deadlist, so that upon reacquiring the lock, sp has 4582 * been remapped. Therefore, the KMEM_SLAB_MOVE_PENDING 4583 * flag causes the slab to be put at the end of the 4584 * deadlist and prevents it from being purged, since we 4585 * plan to destroy it here after reacquiring the lock. 4586 */ 4587 mutex_enter(&cp->cache_lock); 4588 ASSERT(sp->slab_flags & KMEM_SLAB_MOVE_PENDING); 4589 sp->slab_flags &= ~KMEM_SLAB_MOVE_PENDING; 4590 4591 /* 4592 * Destroy the slab now if it was completely freed while 4593 * we dropped cache_lock. 4594 */ 4595 if (sp->slab_refcnt == 0) { 4596 list_t *deadlist = 4597 &cp->cache_defrag->kmd_deadlist; 4598 4599 ASSERT(!list_is_empty(deadlist)); 4600 ASSERT(list_link_active((list_node_t *) 4601 &sp->slab_link)); 4602 4603 list_remove(deadlist, sp); 4604 cp->cache_defrag->kmd_deadcount--; 4605 cp->cache_slab_destroy++; 4606 mutex_exit(&cp->cache_lock); 4607 kmem_slab_destroy(cp, sp); 4608 KMEM_STAT_ADD(kmem_move_stats. 4609 kms_dead_slabs_freed); 4610 KMEM_STAT_ADD(kmem_move_stats. 4611 kms_endscan_slab_destroyed); 4612 mutex_enter(&cp->cache_lock); 4613 /* 4614 * Since we can't pick up the scan where we left 4615 * off, abort the scan and say nothing about the 4616 * number of reclaimable slabs. 4617 */ 4618 return (-1); 4619 } 4620 4621 if (!success) { 4622 /* 4623 * Abort the scan if there is not enough memory 4624 * for the request and say nothing about the 4625 * number of reclaimable slabs. 4626 */ 4627 KMEM_STAT_ADD( 4628 kmem_move_stats.kms_endscan_nomem); 4629 return (-1); 4630 } 4631 4632 /* 4633 * The slab may have been completely allocated while the 4634 * lock was dropped. 4635 */ 4636 if (KMEM_SLAB_IS_ALL_USED(sp)) { 4637 KMEM_STAT_ADD( 4638 kmem_move_stats.kms_endscan_slab_all_used); 4639 return (-1); 4640 } 4641 4642 /* 4643 * The slab's position changed while the lock was 4644 * dropped, so we don't know where we are in the 4645 * sequence any more. 4646 */ 4647 if (sp->slab_refcnt != refcnt) { 4648 KMEM_STAT_ADD( 4649 kmem_move_stats.kms_endscan_refcnt_changed); 4650 return (-1); 4651 } 4652 if ((sp->slab_flags & KMEM_SLAB_NOMOVE) != nomove) { 4653 KMEM_STAT_ADD( 4654 kmem_move_stats.kms_endscan_nomove_changed); 4655 return (-1); 4656 } 4657 4658 /* 4659 * Generating a move request allocates a destination 4660 * buffer from the slab layer, bumping the first slab if 4661 * it is completely allocated. 4662 */ 4663 ASSERT(!avl_is_empty(&cp->cache_partial_slabs)); 4664 if (sp == avl_first(&cp->cache_partial_slabs)) { 4665 goto end_scan; 4666 } 4667 } 4668 } 4669 end_scan: 4670 4671 KMEM_STAT_COND_ADD(sp == avl_first(&cp->cache_partial_slabs), 4672 kmem_move_stats.kms_endscan_freelist); 4673 4674 return (s); 4675 } 4676 4677 typedef struct kmem_move_notify_args { 4678 kmem_cache_t *kmna_cache; 4679 void *kmna_buf; 4680 } kmem_move_notify_args_t; 4681 4682 static void 4683 kmem_cache_move_notify_task(void *arg) 4684 { 4685 kmem_move_notify_args_t *args = arg; 4686 kmem_cache_t *cp = args->kmna_cache; 4687 void *buf = args->kmna_buf; 4688 kmem_slab_t *sp; 4689 4690 ASSERT(taskq_member(kmem_taskq, curthread)); 4691 ASSERT(list_link_active(&cp->cache_link)); 4692 4693 kmem_free(args, sizeof (kmem_move_notify_args_t)); 4694 mutex_enter(&cp->cache_lock); 4695 sp = kmem_slab_allocated(cp, NULL, buf); 4696 4697 /* Ignore the notification if the buffer is no longer allocated. */ 4698 if (sp == NULL) { 4699 mutex_exit(&cp->cache_lock); 4700 return; 4701 } 4702 4703 /* Ignore the notification if there's no reason to move the buffer. */ 4704 if (avl_numnodes(&cp->cache_partial_slabs) > 1) { 4705 /* 4706 * So far the notification is not ignored. Ignore the 4707 * notification if the slab is not marked by an earlier refusal 4708 * to move a buffer. 4709 */ 4710 if (!(sp->slab_flags & KMEM_SLAB_NOMOVE) && 4711 (sp->slab_later_count == 0)) { 4712 mutex_exit(&cp->cache_lock); 4713 return; 4714 } 4715 4716 kmem_slab_move_yes(cp, sp, buf); 4717 ASSERT(!(sp->slab_flags & KMEM_SLAB_MOVE_PENDING)); 4718 sp->slab_flags |= KMEM_SLAB_MOVE_PENDING; 4719 mutex_exit(&cp->cache_lock); 4720 /* see kmem_move_buffers() about dropping the lock */ 4721 (void) kmem_move_begin(cp, sp, buf, KMM_NOTIFY); 4722 mutex_enter(&cp->cache_lock); 4723 ASSERT(sp->slab_flags & KMEM_SLAB_MOVE_PENDING); 4724 sp->slab_flags &= ~KMEM_SLAB_MOVE_PENDING; 4725 if (sp->slab_refcnt == 0) { 4726 list_t *deadlist = &cp->cache_defrag->kmd_deadlist; 4727 4728 ASSERT(!list_is_empty(deadlist)); 4729 ASSERT(list_link_active((list_node_t *) 4730 &sp->slab_link)); 4731 4732 list_remove(deadlist, sp); 4733 cp->cache_defrag->kmd_deadcount--; 4734 cp->cache_slab_destroy++; 4735 mutex_exit(&cp->cache_lock); 4736 kmem_slab_destroy(cp, sp); 4737 KMEM_STAT_ADD(kmem_move_stats.kms_dead_slabs_freed); 4738 return; 4739 } 4740 } else { 4741 kmem_slab_move_yes(cp, sp, buf); 4742 } 4743 mutex_exit(&cp->cache_lock); 4744 } 4745 4746 void 4747 kmem_cache_move_notify(kmem_cache_t *cp, void *buf) 4748 { 4749 kmem_move_notify_args_t *args; 4750 4751 KMEM_STAT_ADD(kmem_move_stats.kms_notify); 4752 args = kmem_alloc(sizeof (kmem_move_notify_args_t), KM_NOSLEEP); 4753 if (args != NULL) { 4754 args->kmna_cache = cp; 4755 args->kmna_buf = buf; 4756 (void) taskq_dispatch(kmem_taskq, 4757 (task_func_t *)kmem_cache_move_notify_task, args, 4758 TQ_NOSLEEP); 4759 } 4760 } 4761 4762 static void 4763 kmem_cache_defrag(kmem_cache_t *cp) 4764 { 4765 size_t n; 4766 4767 ASSERT(cp->cache_defrag != NULL); 4768 4769 mutex_enter(&cp->cache_lock); 4770 n = avl_numnodes(&cp->cache_partial_slabs); 4771 if (n > 1) { 4772 /* kmem_move_buffers() drops and reacquires cache_lock */ 4773 (void) kmem_move_buffers(cp, n, 0, KMM_DESPERATE); 4774 KMEM_STAT_ADD(kmem_move_stats.kms_defrags); 4775 } 4776 mutex_exit(&cp->cache_lock); 4777 } 4778 4779 /* Is this cache above the fragmentation threshold? */ 4780 static boolean_t 4781 kmem_cache_frag_threshold(kmem_cache_t *cp, uint64_t nfree) 4782 { 4783 if (avl_numnodes(&cp->cache_partial_slabs) <= 1) 4784 return (B_FALSE); 4785 4786 /* 4787 * nfree kmem_frag_numer 4788 * ------------------ > --------------- 4789 * cp->cache_buftotal kmem_frag_denom 4790 */ 4791 return ((nfree * kmem_frag_denom) > 4792 (cp->cache_buftotal * kmem_frag_numer)); 4793 } 4794 4795 static boolean_t 4796 kmem_cache_is_fragmented(kmem_cache_t *cp, boolean_t *doreap) 4797 { 4798 boolean_t fragmented; 4799 uint64_t nfree; 4800 4801 ASSERT(MUTEX_HELD(&cp->cache_lock)); 4802 *doreap = B_FALSE; 4803 4804 if (!kmem_move_fulltilt && ((cp->cache_complete_slab_count + 4805 avl_numnodes(&cp->cache_partial_slabs)) < kmem_frag_minslabs)) 4806 return (B_FALSE); 4807 4808 nfree = cp->cache_bufslab; 4809 fragmented = kmem_cache_frag_threshold(cp, nfree); 4810 /* 4811 * Free buffers in the magazine layer appear allocated from the point of 4812 * view of the slab layer. We want to know if the slab layer would 4813 * appear fragmented if we included free buffers from magazines that 4814 * have fallen out of the working set. 4815 */ 4816 if (!fragmented) { 4817 long reap; 4818 4819 mutex_enter(&cp->cache_depot_lock); 4820 reap = MIN(cp->cache_full.ml_reaplimit, cp->cache_full.ml_min); 4821 reap = MIN(reap, cp->cache_full.ml_total); 4822 mutex_exit(&cp->cache_depot_lock); 4823 4824 nfree += ((uint64_t)reap * cp->cache_magtype->mt_magsize); 4825 if (kmem_cache_frag_threshold(cp, nfree)) { 4826 *doreap = B_TRUE; 4827 } 4828 } 4829 4830 return (fragmented); 4831 } 4832 4833 /* Called periodically from kmem_taskq */ 4834 static void 4835 kmem_cache_scan(kmem_cache_t *cp) 4836 { 4837 boolean_t reap = B_FALSE; 4838 4839 ASSERT(taskq_member(kmem_taskq, curthread)); 4840 ASSERT(cp->cache_defrag != NULL); 4841 4842 mutex_enter(&cp->cache_lock); 4843 4844 if (kmem_cache_is_fragmented(cp, &reap)) { 4845 kmem_defrag_t *kmd = cp->cache_defrag; 4846 size_t slabs_found; 4847 4848 /* 4849 * Consolidate reclaimable slabs from the end of the partial 4850 * slab list (scan at most kmem_reclaim_scan_range slabs to find 4851 * reclaimable slabs). Keep track of how many candidate slabs we 4852 * looked for and how many we actually found so we can adjust 4853 * the definition of a candidate slab if we're having trouble 4854 * finding them. 4855 * 4856 * kmem_move_buffers() drops and reacquires cache_lock. 4857 */ 4858 slabs_found = kmem_move_buffers(cp, kmem_reclaim_scan_range, 4859 kmem_reclaim_max_slabs, 0); 4860 if (slabs_found >= 0) { 4861 kmd->kmd_slabs_sought += kmem_reclaim_max_slabs; 4862 kmd->kmd_slabs_found += slabs_found; 4863 } 4864 4865 if (++kmd->kmd_scans >= kmem_reclaim_scan_range) { 4866 kmd->kmd_scans = 0; 4867 4868 /* 4869 * If we had difficulty finding candidate slabs in 4870 * previous scans, adjust the threshold so that 4871 * candidates are easier to find. 4872 */ 4873 if (kmd->kmd_slabs_found == kmd->kmd_slabs_sought) { 4874 kmem_adjust_reclaim_threshold(kmd, -1); 4875 } else if ((kmd->kmd_slabs_found * 2) < 4876 kmd->kmd_slabs_sought) { 4877 kmem_adjust_reclaim_threshold(kmd, 1); 4878 } 4879 kmd->kmd_slabs_sought = 0; 4880 kmd->kmd_slabs_found = 0; 4881 } 4882 } else { 4883 kmem_reset_reclaim_threshold(cp->cache_defrag); 4884 #ifdef DEBUG 4885 if (avl_numnodes(&cp->cache_partial_slabs) > 1) { 4886 /* 4887 * In a debug kernel we want the consolidator to 4888 * run occasionally even when there is plenty of 4889 * memory. 4890 */ 4891 uint32_t debug_rand; 4892 4893 (void) random_get_bytes((uint8_t *)&debug_rand, 4); 4894 if (!kmem_move_noreap && 4895 ((debug_rand % kmem_mtb_reap) == 0)) { 4896 mutex_exit(&cp->cache_lock); 4897 kmem_cache_reap(cp); 4898 KMEM_STAT_ADD(kmem_move_stats.kms_debug_reaps); 4899 return; 4900 } else if ((debug_rand % kmem_mtb_move) == 0) { 4901 (void) kmem_move_buffers(cp, 4902 kmem_reclaim_scan_range, 1, 0); 4903 KMEM_STAT_ADD(kmem_move_stats. 4904 kms_debug_move_scans); 4905 } 4906 } 4907 #endif /* DEBUG */ 4908 } 4909 4910 mutex_exit(&cp->cache_lock); 4911 4912 if (reap) { 4913 KMEM_STAT_ADD(kmem_move_stats.kms_scan_depot_ws_reaps); 4914 kmem_depot_ws_reap(cp); 4915 } 4916 } 4917