pktqueue.c revision 1.8.6.3
1 1.8.6.2 tls /* $NetBSD: pktqueue.c,v 1.8.6.3 2017/12/03 11:39:02 jdolecek Exp $ */ 2 1.8.6.2 tls 3 1.8.6.2 tls /*- 4 1.8.6.2 tls * Copyright (c) 2014 The NetBSD Foundation, Inc. 5 1.8.6.2 tls * All rights reserved. 6 1.8.6.2 tls * 7 1.8.6.2 tls * This code is derived from software contributed to The NetBSD Foundation 8 1.8.6.2 tls * by Mindaugas Rasiukevicius. 9 1.8.6.2 tls * 10 1.8.6.2 tls * Redistribution and use in source and binary forms, with or without 11 1.8.6.2 tls * modification, are permitted provided that the following conditions 12 1.8.6.2 tls * are met: 13 1.8.6.2 tls * 1. Redistributions of source code must retain the above copyright 14 1.8.6.2 tls * notice, this list of conditions and the following disclaimer. 15 1.8.6.2 tls * 2. Redistributions in binary form must reproduce the above copyright 16 1.8.6.2 tls * notice, this list of conditions and the following disclaimer in the 17 1.8.6.2 tls * documentation and/or other materials provided with the distribution. 18 1.8.6.2 tls * 19 1.8.6.2 tls * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 20 1.8.6.2 tls * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 21 1.8.6.2 tls * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 22 1.8.6.2 tls * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 23 1.8.6.2 tls * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 24 1.8.6.2 tls * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 25 1.8.6.2 tls * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 26 1.8.6.2 tls * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 27 1.8.6.2 tls * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 28 1.8.6.2 tls * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 29 1.8.6.2 tls * POSSIBILITY OF SUCH DAMAGE. 30 1.8.6.2 tls */ 31 1.8.6.2 tls 32 1.8.6.2 tls /* 33 1.8.6.2 tls * The packet queue (pktqueue) interface is a lockless IP input queue 34 1.8.6.2 tls * which also abstracts and handles network ISR scheduling. It provides 35 1.8.6.2 tls * a mechanism to enable receiver-side packet steering (RPS). 36 1.8.6.2 tls */ 37 1.8.6.2 tls 38 1.8.6.2 tls #include <sys/cdefs.h> 39 1.8.6.2 tls __KERNEL_RCSID(0, "$NetBSD: pktqueue.c,v 1.8.6.3 2017/12/03 11:39:02 jdolecek Exp $"); 40 1.8.6.2 tls 41 1.8.6.2 tls #include <sys/param.h> 42 1.8.6.2 tls #include <sys/types.h> 43 1.8.6.2 tls 44 1.8.6.2 tls #include <sys/atomic.h> 45 1.8.6.2 tls #include <sys/cpu.h> 46 1.8.6.2 tls #include <sys/pcq.h> 47 1.8.6.2 tls #include <sys/intr.h> 48 1.8.6.2 tls #include <sys/mbuf.h> 49 1.8.6.2 tls #include <sys/proc.h> 50 1.8.6.2 tls #include <sys/percpu.h> 51 1.8.6.2 tls 52 1.8.6.2 tls #include <net/pktqueue.h> 53 1.8.6.2 tls 54 1.8.6.2 tls /* 55 1.8.6.2 tls * WARNING: update this if struct pktqueue changes. 56 1.8.6.2 tls */ 57 1.8.6.2 tls #define PKTQ_CLPAD \ 58 1.8.6.2 tls MAX(COHERENCY_UNIT, COHERENCY_UNIT - sizeof(kmutex_t) - sizeof(u_int)) 59 1.8.6.2 tls 60 1.8.6.2 tls struct pktqueue { 61 1.8.6.2 tls /* 62 1.8.6.2 tls * The lock used for a barrier mechanism. The barrier counter, 63 1.8.6.2 tls * as well as the drop counter, are managed atomically though. 64 1.8.6.2 tls * Ensure this group is in a separate cache line. 65 1.8.6.2 tls */ 66 1.8.6.2 tls kmutex_t pq_lock; 67 1.8.6.2 tls volatile u_int pq_barrier; 68 1.8.6.2 tls uint8_t _pad[PKTQ_CLPAD]; 69 1.8.6.2 tls 70 1.8.6.2 tls /* The size of the queue, counters and the interrupt handler. */ 71 1.8.6.2 tls u_int pq_maxlen; 72 1.8.6.2 tls percpu_t * pq_counters; 73 1.8.6.2 tls void * pq_sih; 74 1.8.6.2 tls 75 1.8.6.2 tls /* Finally, per-CPU queues. */ 76 1.8.6.2 tls pcq_t * pq_queue[]; 77 1.8.6.2 tls }; 78 1.8.6.2 tls 79 1.8.6.2 tls /* The counters of the packet queue. */ 80 1.8.6.2 tls #define PQCNT_ENQUEUE 0 81 1.8.6.2 tls #define PQCNT_DEQUEUE 1 82 1.8.6.2 tls #define PQCNT_DROP 2 83 1.8.6.2 tls #define PQCNT_NCOUNTERS 3 84 1.8.6.2 tls 85 1.8.6.2 tls typedef struct { 86 1.8.6.2 tls uint64_t count[PQCNT_NCOUNTERS]; 87 1.8.6.2 tls } pktq_counters_t; 88 1.8.6.2 tls 89 1.8.6.2 tls /* Special marker value used by pktq_barrier() mechanism. */ 90 1.8.6.2 tls #define PKTQ_MARKER ((void *)(~0ULL)) 91 1.8.6.2 tls 92 1.8.6.2 tls /* 93 1.8.6.2 tls * The total size of pktqueue_t which depends on the number of CPUs. 94 1.8.6.2 tls */ 95 1.8.6.2 tls #define PKTQUEUE_STRUCT_LEN(ncpu) \ 96 1.8.6.2 tls roundup2(offsetof(pktqueue_t, pq_queue[ncpu]), coherency_unit) 97 1.8.6.2 tls 98 1.8.6.2 tls pktqueue_t * 99 1.8.6.2 tls pktq_create(size_t maxlen, void (*intrh)(void *), void *sc) 100 1.8.6.2 tls { 101 1.8.6.2 tls const u_int sflags = SOFTINT_NET | SOFTINT_MPSAFE | SOFTINT_RCPU; 102 1.8.6.2 tls const size_t len = PKTQUEUE_STRUCT_LEN(ncpu); 103 1.8.6.2 tls pktqueue_t *pq; 104 1.8.6.2 tls percpu_t *pc; 105 1.8.6.2 tls void *sih; 106 1.8.6.2 tls 107 1.8.6.3 jdolecek pc = percpu_alloc(sizeof(pktq_counters_t)); 108 1.8.6.2 tls if ((sih = softint_establish(sflags, intrh, sc)) == NULL) { 109 1.8.6.2 tls percpu_free(pc, sizeof(pktq_counters_t)); 110 1.8.6.2 tls return NULL; 111 1.8.6.2 tls } 112 1.8.6.2 tls 113 1.8.6.2 tls pq = kmem_zalloc(len, KM_SLEEP); 114 1.8.6.2 tls for (u_int i = 0; i < ncpu; i++) { 115 1.8.6.2 tls pq->pq_queue[i] = pcq_create(maxlen, KM_SLEEP); 116 1.8.6.2 tls } 117 1.8.6.2 tls mutex_init(&pq->pq_lock, MUTEX_DEFAULT, IPL_NONE); 118 1.8.6.2 tls pq->pq_maxlen = maxlen; 119 1.8.6.2 tls pq->pq_counters = pc; 120 1.8.6.2 tls pq->pq_sih = sih; 121 1.8.6.2 tls 122 1.8.6.2 tls return pq; 123 1.8.6.2 tls } 124 1.8.6.2 tls 125 1.8.6.2 tls void 126 1.8.6.2 tls pktq_destroy(pktqueue_t *pq) 127 1.8.6.2 tls { 128 1.8.6.2 tls const size_t len = PKTQUEUE_STRUCT_LEN(ncpu); 129 1.8.6.2 tls 130 1.8.6.2 tls for (u_int i = 0; i < ncpu; i++) { 131 1.8.6.2 tls pcq_t *q = pq->pq_queue[i]; 132 1.8.6.2 tls KASSERT(pcq_peek(q) == NULL); 133 1.8.6.2 tls pcq_destroy(q); 134 1.8.6.2 tls } 135 1.8.6.2 tls percpu_free(pq->pq_counters, sizeof(pktq_counters_t)); 136 1.8.6.2 tls softint_disestablish(pq->pq_sih); 137 1.8.6.2 tls mutex_destroy(&pq->pq_lock); 138 1.8.6.2 tls kmem_free(pq, len); 139 1.8.6.2 tls } 140 1.8.6.2 tls 141 1.8.6.2 tls /* 142 1.8.6.2 tls * - pktq_inc_counter: increment the counter given an ID. 143 1.8.6.2 tls * - pktq_collect_counts: handler to sum up the counts from each CPU. 144 1.8.6.2 tls * - pktq_getcount: return the effective count given an ID. 145 1.8.6.2 tls */ 146 1.8.6.2 tls 147 1.8.6.2 tls static inline void 148 1.8.6.2 tls pktq_inc_count(pktqueue_t *pq, u_int i) 149 1.8.6.2 tls { 150 1.8.6.2 tls percpu_t *pc = pq->pq_counters; 151 1.8.6.2 tls pktq_counters_t *c; 152 1.8.6.2 tls 153 1.8.6.2 tls c = percpu_getref(pc); 154 1.8.6.2 tls c->count[i]++; 155 1.8.6.2 tls percpu_putref(pc); 156 1.8.6.2 tls } 157 1.8.6.2 tls 158 1.8.6.2 tls static void 159 1.8.6.2 tls pktq_collect_counts(void *mem, void *arg, struct cpu_info *ci) 160 1.8.6.2 tls { 161 1.8.6.2 tls const pktq_counters_t *c = mem; 162 1.8.6.2 tls pktq_counters_t *sum = arg; 163 1.8.6.2 tls 164 1.8.6.2 tls for (u_int i = 0; i < PQCNT_NCOUNTERS; i++) { 165 1.8.6.2 tls sum->count[i] += c->count[i]; 166 1.8.6.2 tls } 167 1.8.6.2 tls } 168 1.8.6.2 tls 169 1.8.6.2 tls uint64_t 170 1.8.6.2 tls pktq_get_count(pktqueue_t *pq, pktq_count_t c) 171 1.8.6.2 tls { 172 1.8.6.2 tls pktq_counters_t sum; 173 1.8.6.2 tls 174 1.8.6.2 tls if (c != PKTQ_MAXLEN) { 175 1.8.6.2 tls memset(&sum, 0, sizeof(sum)); 176 1.8.6.2 tls percpu_foreach(pq->pq_counters, pktq_collect_counts, &sum); 177 1.8.6.2 tls } 178 1.8.6.2 tls switch (c) { 179 1.8.6.2 tls case PKTQ_NITEMS: 180 1.8.6.2 tls return sum.count[PQCNT_ENQUEUE] - sum.count[PQCNT_DEQUEUE]; 181 1.8.6.2 tls case PKTQ_DROPS: 182 1.8.6.2 tls return sum.count[PQCNT_DROP]; 183 1.8.6.2 tls case PKTQ_MAXLEN: 184 1.8.6.2 tls return pq->pq_maxlen; 185 1.8.6.2 tls } 186 1.8.6.2 tls return 0; 187 1.8.6.2 tls } 188 1.8.6.2 tls 189 1.8.6.2 tls uint32_t 190 1.8.6.2 tls pktq_rps_hash(const struct mbuf *m __unused) 191 1.8.6.2 tls { 192 1.8.6.2 tls /* 193 1.8.6.2 tls * XXX: No distribution yet; the softnet_lock contention 194 1.8.6.2 tls * XXX: must be eliminated first. 195 1.8.6.2 tls */ 196 1.8.6.2 tls return 0; 197 1.8.6.2 tls } 198 1.8.6.2 tls 199 1.8.6.2 tls /* 200 1.8.6.2 tls * pktq_enqueue: inject the packet into the end of the queue. 201 1.8.6.2 tls * 202 1.8.6.2 tls * => Must be called from the interrupt or with the preemption disabled. 203 1.8.6.2 tls * => Consumes the packet and returns true on success. 204 1.8.6.2 tls * => Returns false on failure; caller is responsible to free the packet. 205 1.8.6.2 tls */ 206 1.8.6.2 tls bool 207 1.8.6.2 tls pktq_enqueue(pktqueue_t *pq, struct mbuf *m, const u_int hash __unused) 208 1.8.6.2 tls { 209 1.8.6.2 tls #if defined(_RUMPKERNEL) || defined(_RUMP_NATIVE_ABI) 210 1.8.6.2 tls const unsigned cpuid = curcpu()->ci_index; 211 1.8.6.2 tls #else 212 1.8.6.2 tls const unsigned cpuid = hash % ncpu; 213 1.8.6.2 tls #endif 214 1.8.6.2 tls 215 1.8.6.2 tls KASSERT(kpreempt_disabled()); 216 1.8.6.2 tls 217 1.8.6.2 tls if (__predict_false(!pcq_put(pq->pq_queue[cpuid], m))) { 218 1.8.6.2 tls pktq_inc_count(pq, PQCNT_DROP); 219 1.8.6.2 tls return false; 220 1.8.6.2 tls } 221 1.8.6.2 tls softint_schedule_cpu(pq->pq_sih, cpu_lookup(cpuid)); 222 1.8.6.2 tls pktq_inc_count(pq, PQCNT_ENQUEUE); 223 1.8.6.2 tls return true; 224 1.8.6.2 tls } 225 1.8.6.2 tls 226 1.8.6.2 tls /* 227 1.8.6.2 tls * pktq_dequeue: take a packet from the queue. 228 1.8.6.2 tls * 229 1.8.6.2 tls * => Must be called with preemption disabled. 230 1.8.6.2 tls * => Must ensure there are not concurrent dequeue calls. 231 1.8.6.2 tls */ 232 1.8.6.2 tls struct mbuf * 233 1.8.6.2 tls pktq_dequeue(pktqueue_t *pq) 234 1.8.6.2 tls { 235 1.8.6.2 tls const struct cpu_info *ci = curcpu(); 236 1.8.6.2 tls const unsigned cpuid = cpu_index(ci); 237 1.8.6.2 tls struct mbuf *m; 238 1.8.6.2 tls 239 1.8.6.2 tls m = pcq_get(pq->pq_queue[cpuid]); 240 1.8.6.2 tls if (__predict_false(m == PKTQ_MARKER)) { 241 1.8.6.2 tls /* Note the marker entry. */ 242 1.8.6.2 tls atomic_inc_uint(&pq->pq_barrier); 243 1.8.6.2 tls return NULL; 244 1.8.6.2 tls } 245 1.8.6.2 tls if (__predict_true(m != NULL)) { 246 1.8.6.2 tls pktq_inc_count(pq, PQCNT_DEQUEUE); 247 1.8.6.2 tls } 248 1.8.6.2 tls return m; 249 1.8.6.2 tls } 250 1.8.6.2 tls 251 1.8.6.2 tls /* 252 1.8.6.2 tls * pktq_barrier: waits for a grace period when all packets enqueued at 253 1.8.6.2 tls * the moment of calling this routine will be processed. This is used 254 1.8.6.2 tls * to ensure that e.g. packets referencing some interface were drained. 255 1.8.6.2 tls */ 256 1.8.6.2 tls void 257 1.8.6.2 tls pktq_barrier(pktqueue_t *pq) 258 1.8.6.2 tls { 259 1.8.6.2 tls u_int pending = 0; 260 1.8.6.2 tls 261 1.8.6.2 tls mutex_enter(&pq->pq_lock); 262 1.8.6.2 tls KASSERT(pq->pq_barrier == 0); 263 1.8.6.2 tls 264 1.8.6.2 tls for (u_int i = 0; i < ncpu; i++) { 265 1.8.6.2 tls pcq_t *q = pq->pq_queue[i]; 266 1.8.6.2 tls 267 1.8.6.2 tls /* If the queue is empty - nothing to do. */ 268 1.8.6.2 tls if (pcq_peek(q) == NULL) { 269 1.8.6.2 tls continue; 270 1.8.6.2 tls } 271 1.8.6.2 tls /* Otherwise, put the marker and entry. */ 272 1.8.6.2 tls while (!pcq_put(q, PKTQ_MARKER)) { 273 1.8.6.2 tls kpause("pktqsync", false, 1, NULL); 274 1.8.6.2 tls } 275 1.8.6.2 tls kpreempt_disable(); 276 1.8.6.2 tls softint_schedule_cpu(pq->pq_sih, cpu_lookup(i)); 277 1.8.6.2 tls kpreempt_enable(); 278 1.8.6.2 tls pending++; 279 1.8.6.2 tls } 280 1.8.6.2 tls 281 1.8.6.2 tls /* Wait for each queue to process the markers. */ 282 1.8.6.2 tls while (pq->pq_barrier != pending) { 283 1.8.6.2 tls kpause("pktqsync", false, 1, NULL); 284 1.8.6.2 tls } 285 1.8.6.2 tls pq->pq_barrier = 0; 286 1.8.6.2 tls mutex_exit(&pq->pq_lock); 287 1.8.6.2 tls } 288 1.8.6.2 tls 289 1.8.6.2 tls /* 290 1.8.6.2 tls * pktq_flush: free mbufs in all queues. 291 1.8.6.2 tls * 292 1.8.6.2 tls * => The caller must ensure there are no concurrent writers or flush calls. 293 1.8.6.2 tls */ 294 1.8.6.2 tls void 295 1.8.6.2 tls pktq_flush(pktqueue_t *pq) 296 1.8.6.2 tls { 297 1.8.6.2 tls struct mbuf *m; 298 1.8.6.2 tls 299 1.8.6.2 tls for (u_int i = 0; i < ncpu; i++) { 300 1.8.6.2 tls while ((m = pcq_get(pq->pq_queue[i])) != NULL) { 301 1.8.6.2 tls pktq_inc_count(pq, PQCNT_DEQUEUE); 302 1.8.6.2 tls m_freem(m); 303 1.8.6.2 tls } 304 1.8.6.2 tls } 305 1.8.6.2 tls } 306 1.8.6.2 tls 307 1.8.6.2 tls /* 308 1.8.6.2 tls * pktq_set_maxlen: create per-CPU queues using a new size and replace 309 1.8.6.2 tls * the existing queues without losing any packets. 310 1.8.6.2 tls */ 311 1.8.6.2 tls int 312 1.8.6.2 tls pktq_set_maxlen(pktqueue_t *pq, size_t maxlen) 313 1.8.6.2 tls { 314 1.8.6.2 tls const u_int slotbytes = ncpu * sizeof(pcq_t *); 315 1.8.6.2 tls pcq_t **qs; 316 1.8.6.2 tls 317 1.8.6.2 tls if (!maxlen || maxlen > PCQ_MAXLEN) 318 1.8.6.2 tls return EINVAL; 319 1.8.6.2 tls if (pq->pq_maxlen == maxlen) 320 1.8.6.2 tls return 0; 321 1.8.6.2 tls 322 1.8.6.2 tls /* First, allocate the new queues and replace them. */ 323 1.8.6.2 tls qs = kmem_zalloc(slotbytes, KM_SLEEP); 324 1.8.6.2 tls for (u_int i = 0; i < ncpu; i++) { 325 1.8.6.2 tls qs[i] = pcq_create(maxlen, KM_SLEEP); 326 1.8.6.2 tls } 327 1.8.6.2 tls mutex_enter(&pq->pq_lock); 328 1.8.6.2 tls for (u_int i = 0; i < ncpu; i++) { 329 1.8.6.2 tls /* Swap: store of a word is atomic. */ 330 1.8.6.2 tls pcq_t *q = pq->pq_queue[i]; 331 1.8.6.2 tls pq->pq_queue[i] = qs[i]; 332 1.8.6.2 tls qs[i] = q; 333 1.8.6.2 tls } 334 1.8.6.2 tls pq->pq_maxlen = maxlen; 335 1.8.6.2 tls mutex_exit(&pq->pq_lock); 336 1.8.6.2 tls 337 1.8.6.2 tls /* 338 1.8.6.2 tls * At this point, the new packets are flowing into the new 339 1.8.6.2 tls * queues. However, the old queues may have some packets 340 1.8.6.2 tls * present which are no longer being processed. We are going 341 1.8.6.2 tls * to re-enqueue them. This may change the order of packet 342 1.8.6.2 tls * arrival, but it is not considered an issue. 343 1.8.6.2 tls * 344 1.8.6.2 tls * There may be in-flight interrupts calling pktq_dequeue() 345 1.8.6.2 tls * which reference the old queues. Issue a barrier to ensure 346 1.8.6.2 tls * that we are going to be the only pcq_get() callers on the 347 1.8.6.2 tls * old queues. 348 1.8.6.2 tls */ 349 1.8.6.2 tls pktq_barrier(pq); 350 1.8.6.2 tls 351 1.8.6.2 tls for (u_int i = 0; i < ncpu; i++) { 352 1.8.6.2 tls struct mbuf *m; 353 1.8.6.2 tls 354 1.8.6.2 tls while ((m = pcq_get(qs[i])) != NULL) { 355 1.8.6.2 tls while (!pcq_put(pq->pq_queue[i], m)) { 356 1.8.6.2 tls kpause("pktqrenq", false, 1, NULL); 357 1.8.6.2 tls } 358 1.8.6.2 tls } 359 1.8.6.2 tls pcq_destroy(qs[i]); 360 1.8.6.2 tls } 361 1.8.6.2 tls 362 1.8.6.2 tls /* Well, that was fun. */ 363 1.8.6.2 tls kmem_free(qs, slotbytes); 364 1.8.6.2 tls return 0; 365 1.8.6.2 tls } 366 1.8.6.2 tls 367 1.8.6.2 tls int 368 1.8.6.2 tls sysctl_pktq_maxlen(SYSCTLFN_ARGS, pktqueue_t *pq) 369 1.8.6.2 tls { 370 1.8.6.2 tls u_int nmaxlen = pktq_get_count(pq, PKTQ_MAXLEN); 371 1.8.6.2 tls struct sysctlnode node = *rnode; 372 1.8.6.2 tls int error; 373 1.8.6.2 tls 374 1.8.6.2 tls node.sysctl_data = &nmaxlen; 375 1.8.6.2 tls error = sysctl_lookup(SYSCTLFN_CALL(&node)); 376 1.8.6.2 tls if (error || newp == NULL) 377 1.8.6.2 tls return error; 378 1.8.6.2 tls return pktq_set_maxlen(pq, nmaxlen); 379 1.8.6.2 tls } 380 1.8.6.2 tls 381 1.8.6.2 tls int 382 1.8.6.2 tls sysctl_pktq_count(SYSCTLFN_ARGS, pktqueue_t *pq, u_int count_id) 383 1.8.6.2 tls { 384 1.8.6.2 tls int count = pktq_get_count(pq, count_id); 385 1.8.6.2 tls struct sysctlnode node = *rnode; 386 1.8.6.2 tls node.sysctl_data = &count; 387 1.8.6.2 tls return sysctl_lookup(SYSCTLFN_CALL(&node)); 388 1.8.6.2 tls } 389
Indexes created Tue Sep 30 20:09:53 GMT 2025