1Using RCU (Read-Copy-Update) for synchronization 2================================================ 3 4Read-copy update (RCU) is a synchronization mechanism that is used to 5protect read-mostly data structures. RCU is very efficient and scalable 6on the read side (it is wait-free), and thus can make the read paths 7extremely fast. 8 9RCU supports concurrency between a single writer and multiple readers, 10thus it is not used alone. Typically, the write-side will use a lock to 11serialize multiple updates, but other approaches are possible (e.g., 12restricting updates to a single task). In QEMU, when a lock is used, 13this will often be the "iothread mutex", also known as the "big QEMU 14lock" (BQL). Also, restricting updates to a single task is done in 15QEMU using the "bottom half" API. 16 17RCU is fundamentally a "wait-to-finish" mechanism. The read side marks 18sections of code with "critical sections", and the update side will wait 19for the execution of all *currently running* critical sections before 20proceeding, or before asynchronously executing a callback. 21 22The key point here is that only the currently running critical sections 23are waited for; critical sections that are started _after_ the beginning 24of the wait do not extend the wait, despite running concurrently with 25the updater. This is the reason why RCU is more scalable than, 26for example, reader-writer locks. It is so much more scalable that 27the system will have a single instance of the RCU mechanism; a single 28mechanism can be used for an arbitrary number of "things", without 29having to worry about things such as contention or deadlocks. 30 31How is this possible? The basic idea is to split updates in two phases, 32"removal" and "reclamation". During removal, we ensure that subsequent 33readers will not be able to get a reference to the old data. After 34removal has completed, a critical section will not be able to access 35the old data. Therefore, critical sections that begin after removal 36do not matter; as soon as all previous critical sections have finished, 37there cannot be any readers who hold references to the data structure, 38and these can now be safely reclaimed (e.g., freed or unref'ed). 39 40Here is a picture: 41 42 thread 1 thread 2 thread 3 43 ------------------- ------------------------ ------------------- 44 enter RCU crit.sec. 45 | finish removal phase 46 | begin wait 47 | | enter RCU crit.sec. 48 exit RCU crit.sec | | 49 complete wait | 50 begin reclamation phase | 51 exit RCU crit.sec. 52 53 54Note how thread 3 is still executing its critical section when thread 2 55starts reclaiming data. This is possible, because the old version of the 56data structure was not accessible at the time thread 3 began executing 57that critical section. 58 59 60RCU API 61======= 62 63The core RCU API is small: 64 65 void rcu_read_lock(void); 66 67 Used by a reader to inform the reclaimer that the reader is 68 entering an RCU read-side critical section. 69 70 void rcu_read_unlock(void); 71 72 Used by a reader to inform the reclaimer that the reader is 73 exiting an RCU read-side critical section. Note that RCU 74 read-side critical sections may be nested and/or overlapping. 75 76 void synchronize_rcu(void); 77 78 Blocks until all pre-existing RCU read-side critical sections 79 on all threads have completed. This marks the end of the removal 80 phase and the beginning of reclamation phase. 81 82 Note that it would be valid for another update to come while 83 synchronize_rcu is running. Because of this, it is better that 84 the updater releases any locks it may hold before calling 85 synchronize_rcu. If this is not possible (for example, because 86 the updater is protected by the BQL), you can use call_rcu. 87 88 void call_rcu1(struct rcu_head * head, 89 void (*func)(struct rcu_head *head)); 90 91 This function invokes func(head) after all pre-existing RCU 92 read-side critical sections on all threads have completed. This 93 marks the end of the removal phase, with func taking care 94 asynchronously of the reclamation phase. 95 96 The foo struct needs to have an rcu_head structure added, 97 perhaps as follows: 98 99 struct foo { 100 struct rcu_head rcu; 101 int a; 102 char b; 103 long c; 104 }; 105 106 so that the reclaimer function can fetch the struct foo address 107 and free it: 108 109 call_rcu1(&foo.rcu, foo_reclaim); 110 111 void foo_reclaim(struct rcu_head *rp) 112 { 113 struct foo *fp = container_of(rp, struct foo, rcu); 114 g_free(fp); 115 } 116 117 For the common case where the rcu_head member is the first of the 118 struct, you can use the following macro. 119 120 void call_rcu(T *p, 121 void (*func)(T *p), 122 field-name); 123 void g_free_rcu(T *p, 124 field-name); 125 126 call_rcu1 is typically used through these macro, in the common case 127 where the "struct rcu_head" is the first field in the struct. If 128 the callback function is g_free, in particular, g_free_rcu can be 129 used. In the above case, one could have written simply: 130 131 g_free_rcu(&foo, rcu); 132 133 typeof(*p) atomic_rcu_read(p); 134 135 atomic_rcu_read() is similar to atomic_mb_read(), but it makes 136 some assumptions on the code that calls it. This allows a more 137 optimized implementation. 138 139 atomic_rcu_read assumes that whenever a single RCU critical 140 section reads multiple shared data, these reads are either 141 data-dependent or need no ordering. This is almost always the 142 case when using RCU, because read-side critical sections typically 143 navigate one or more pointers (the pointers that are changed on 144 every update) until reaching a data structure of interest, 145 and then read from there. 146 147 RCU read-side critical sections must use atomic_rcu_read() to 148 read data, unless concurrent writes are prevented by another 149 synchronization mechanism. 150 151 Furthermore, RCU read-side critical sections should traverse the 152 data structure in a single direction, opposite to the direction 153 in which the updater initializes it. 154 155 void atomic_rcu_set(p, typeof(*p) v); 156 157 atomic_rcu_set() is also similar to atomic_mb_set(), and it also 158 makes assumptions on the code that calls it in order to allow a more 159 optimized implementation. 160 161 In particular, atomic_rcu_set() suffices for synchronization 162 with readers, if the updater never mutates a field within a 163 data item that is already accessible to readers. This is the 164 case when initializing a new copy of the RCU-protected data 165 structure; just ensure that initialization of *p is carried out 166 before atomic_rcu_set() makes the data item visible to readers. 167 If this rule is observed, writes will happen in the opposite 168 order as reads in the RCU read-side critical sections (or if 169 there is just one update), and there will be no need for other 170 synchronization mechanism to coordinate the accesses. 171 172The following APIs must be used before RCU is used in a thread: 173 174 void rcu_register_thread(void); 175 176 Mark a thread as taking part in the RCU mechanism. Such a thread 177 will have to report quiescent points regularly, either manually 178 or through the QemuCond/QemuSemaphore/QemuEvent APIs. 179 180 void rcu_unregister_thread(void); 181 182 Mark a thread as not taking part anymore in the RCU mechanism. 183 It is not a problem if such a thread reports quiescent points, 184 either manually or by using the QemuCond/QemuSemaphore/QemuEvent 185 APIs. 186 187Note that these APIs are relatively heavyweight, and should _not_ be 188nested. 189 190Convenience macros 191================== 192 193Two macros are provided that automatically release the read lock at the 194end of the scope. 195 196 RCU_READ_LOCK_GUARD() 197 198 Takes the lock and will release it at the end of the block it's 199 used in. 200 201 WITH_RCU_READ_LOCK_GUARD() { code } 202 203 Is used at the head of a block to protect the code within the block. 204 205Note that 'goto'ing out of the guarded block will also drop the lock. 206 207DIFFERENCES WITH LINUX 208====================== 209 210- Waiting on a mutex is possible, though discouraged, within an RCU critical 211 section. This is because spinlocks are rarely (if ever) used in userspace 212 programming; not allowing this would prevent upgrading an RCU read-side 213 critical section to become an updater. 214 215- atomic_rcu_read and atomic_rcu_set replace rcu_dereference and 216 rcu_assign_pointer. They take a _pointer_ to the variable being accessed. 217 218- call_rcu is a macro that has an extra argument (the name of the first 219 field in the struct, which must be a struct rcu_head), and expects the 220 type of the callback's argument to be the type of the first argument. 221 call_rcu1 is the same as Linux's call_rcu. 222 223 224RCU PATTERNS 225============ 226 227Many patterns using read-writer locks translate directly to RCU, with 228the advantages of higher scalability and deadlock immunity. 229 230In general, RCU can be used whenever it is possible to create a new 231"version" of a data structure every time the updater runs. This may 232sound like a very strict restriction, however: 233 234- the updater does not mean "everything that writes to a data structure", 235 but rather "everything that involves a reclamation step". See the 236 array example below 237 238- in some cases, creating a new version of a data structure may actually 239 be very cheap. For example, modifying the "next" pointer of a singly 240 linked list is effectively creating a new version of the list. 241 242Here are some frequently-used RCU idioms that are worth noting. 243 244 245RCU list processing 246------------------- 247 248TBD (not yet used in QEMU) 249 250 251RCU reference counting 252---------------------- 253 254Because grace periods are not allowed to complete while there is an RCU 255read-side critical section in progress, the RCU read-side primitives 256may be used as a restricted reference-counting mechanism. For example, 257consider the following code fragment: 258 259 rcu_read_lock(); 260 p = atomic_rcu_read(&foo); 261 /* do something with p. */ 262 rcu_read_unlock(); 263 264The RCU read-side critical section ensures that the value of "p" remains 265valid until after the rcu_read_unlock(). In some sense, it is acquiring 266a reference to p that is later released when the critical section ends. 267The write side looks simply like this (with appropriate locking): 268 269 qemu_mutex_lock(&foo_mutex); 270 old = foo; 271 atomic_rcu_set(&foo, new); 272 qemu_mutex_unlock(&foo_mutex); 273 synchronize_rcu(); 274 free(old); 275 276If the processing cannot be done purely within the critical section, it 277is possible to combine this idiom with a "real" reference count: 278 279 rcu_read_lock(); 280 p = atomic_rcu_read(&foo); 281 foo_ref(p); 282 rcu_read_unlock(); 283 /* do something with p. */ 284 foo_unref(p); 285 286The write side can be like this: 287 288 qemu_mutex_lock(&foo_mutex); 289 old = foo; 290 atomic_rcu_set(&foo, new); 291 qemu_mutex_unlock(&foo_mutex); 292 synchronize_rcu(); 293 foo_unref(old); 294 295or with call_rcu: 296 297 qemu_mutex_lock(&foo_mutex); 298 old = foo; 299 atomic_rcu_set(&foo, new); 300 qemu_mutex_unlock(&foo_mutex); 301 call_rcu(foo_unref, old, rcu); 302 303In both cases, the write side only performs removal. Reclamation 304happens when the last reference to a "foo" object is dropped. 305Using synchronize_rcu() is undesirably expensive, because the 306last reference may be dropped on the read side. Hence you can 307use call_rcu() instead: 308 309 foo_unref(struct foo *p) { 310 if (atomic_fetch_dec(&p->refcount) == 1) { 311 call_rcu(foo_destroy, p, rcu); 312 } 313 } 314 315 316Note that the same idioms would be possible with reader/writer 317locks: 318 319 read_lock(&foo_rwlock); write_mutex_lock(&foo_rwlock); 320 p = foo; p = foo; 321 /* do something with p. */ foo = new; 322 read_unlock(&foo_rwlock); free(p); 323 write_mutex_unlock(&foo_rwlock); 324 free(p); 325 326 ------------------------------------------------------------------ 327 328 read_lock(&foo_rwlock); write_mutex_lock(&foo_rwlock); 329 p = foo; old = foo; 330 foo_ref(p); foo = new; 331 read_unlock(&foo_rwlock); foo_unref(old); 332 /* do something with p. */ write_mutex_unlock(&foo_rwlock); 333 read_lock(&foo_rwlock); 334 foo_unref(p); 335 read_unlock(&foo_rwlock); 336 337foo_unref could use a mechanism such as bottom halves to move deallocation 338out of the write-side critical section. 339 340 341RCU resizable arrays 342-------------------- 343 344Resizable arrays can be used with RCU. The expensive RCU synchronization 345(or call_rcu) only needs to take place when the array is resized. 346The two items to take care of are: 347 348- ensuring that the old version of the array is available between removal 349 and reclamation; 350 351- avoiding mismatches in the read side between the array data and the 352 array size. 353 354The first problem is avoided simply by not using realloc. Instead, 355each resize will allocate a new array and copy the old data into it. 356The second problem would arise if the size and the data pointers were 357two members of a larger struct: 358 359 struct mystuff { 360 ... 361 int data_size; 362 int data_alloc; 363 T *data; 364 ... 365 }; 366 367Instead, we store the size of the array with the array itself: 368 369 struct arr { 370 int size; 371 int alloc; 372 T data[]; 373 }; 374 struct arr *global_array; 375 376 read side: 377 rcu_read_lock(); 378 struct arr *array = atomic_rcu_read(&global_array); 379 x = i < array->size ? array->data[i] : -1; 380 rcu_read_unlock(); 381 return x; 382 383 write side (running under a lock): 384 if (global_array->size == global_array->alloc) { 385 /* Creating a new version. */ 386 new_array = g_malloc(sizeof(struct arr) + 387 global_array->alloc * 2 * sizeof(T)); 388 new_array->size = global_array->size; 389 new_array->alloc = global_array->alloc * 2; 390 memcpy(new_array->data, global_array->data, 391 global_array->alloc * sizeof(T)); 392 393 /* Removal phase. */ 394 old_array = global_array; 395 atomic_rcu_set(&new_array->data, new_array); 396 synchronize_rcu(); 397 398 /* Reclamation phase. */ 399 free(old_array); 400 } 401 402 403SOURCES 404======= 405 406* Documentation/RCU/ from the Linux kernel 407