sys/net/pktqueue.c

1.8.6.2  tls /*	$NetBSD: pktqueue.c,v 1.8.6.2 2014/08/20 00:04:34 tls Exp $	*/
1.8.6.2  tls
1.8.6.2  tls /*-
1.8.6.2  tls  * Copyright (c) 2014 The NetBSD Foundation, Inc.
1.8.6.2  tls  * All rights reserved.
1.8.6.2  tls  *
1.8.6.2  tls  * This code is derived from software contributed to The NetBSD Foundation
1.8.6.2  tls  * by Mindaugas Rasiukevicius.
1.8.6.2  tls  *
1.8.6.2  tls  * Redistribution and use in source and binary forms, with or without
1.8.6.2  tls  * modification, are permitted provided that the following conditions
1.8.6.2  tls  * are met:
1.8.6.2  tls  * 1. Redistributions of source code must retain the above copyright
1.8.6.2  tls  *    notice, this list of conditions and the following disclaimer.
1.8.6.2  tls  * 2. Redistributions in binary form must reproduce the above copyright
1.8.6.2  tls  *    notice, this list of conditions and the following disclaimer in the
1.8.6.2  tls  *    documentation and/or other materials provided with the distribution.
1.8.6.2  tls  *
1.8.6.2  tls  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
1.8.6.2  tls  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
1.8.6.2  tls  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
1.8.6.2  tls  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
1.8.6.2  tls  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
1.8.6.2  tls  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
1.8.6.2  tls  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
1.8.6.2  tls  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
1.8.6.2  tls  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
1.8.6.2  tls  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
1.8.6.2  tls  * POSSIBILITY OF SUCH DAMAGE.
1.8.6.2  tls  */
1.8.6.2  tls
1.8.6.2  tls /*
1.8.6.2  tls  * The packet queue (pktqueue) interface is a lockless IP input queue
1.8.6.2  tls  * which also abstracts and handles network ISR scheduling.  It provides
1.8.6.2  tls  * a mechanism to enable receiver-side packet steering (RPS).
1.8.6.2  tls  */
1.8.6.2  tls
1.8.6.2  tls #include <sys/cdefs.h>
1.8.6.2  tls __KERNEL_RCSID(0, "$NetBSD: pktqueue.c,v 1.8.6.2 2014/08/20 00:04:34 tls Exp $");
1.8.6.2  tls
1.8.6.2  tls #include <sys/param.h>
1.8.6.2  tls #include <sys/types.h>
1.8.6.2  tls
1.8.6.2  tls #include <sys/atomic.h>
1.8.6.2  tls #include <sys/cpu.h>
1.8.6.2  tls #include <sys/pcq.h>
1.8.6.2  tls #include <sys/intr.h>
1.8.6.2  tls #include <sys/mbuf.h>
1.8.6.2  tls #include <sys/proc.h>
1.8.6.2  tls #include <sys/percpu.h>
1.8.6.2  tls
1.8.6.2  tls #include <net/pktqueue.h>
1.8.6.2  tls
1.8.6.2  tls /*
1.8.6.2  tls  * WARNING: update this if struct pktqueue changes.
1.8.6.2  tls  */
1.8.6.2  tls #define	PKTQ_CLPAD	\
1.8.6.2  tls     MAX(COHERENCY_UNIT, COHERENCY_UNIT - sizeof(kmutex_t) - sizeof(u_int))
1.8.6.2  tls
1.8.6.2  tls struct pktqueue {
1.8.6.2  tls 	/*
1.8.6.2  tls 	 * The lock used for a barrier mechanism.  The barrier counter,
1.8.6.2  tls 	 * as well as the drop counter, are managed atomically though.
1.8.6.2  tls 	 * Ensure this group is in a separate cache line.
1.8.6.2  tls 	 */
1.8.6.2  tls 	kmutex_t	pq_lock;
1.8.6.2  tls 	volatile u_int	pq_barrier;
1.8.6.2  tls 	uint8_t		_pad[PKTQ_CLPAD];
1.8.6.2  tls
1.8.6.2  tls 	/* The size of the queue, counters and the interrupt handler. */
1.8.6.2  tls 	u_int		pq_maxlen;
1.8.6.2  tls 	percpu_t *	pq_counters;
1.8.6.2  tls 	void *		pq_sih;
1.8.6.2  tls
1.8.6.2  tls 	/* Finally, per-CPU queues. */
1.8.6.2  tls 	pcq_t *		pq_queue[];
1.8.6.2  tls };
1.8.6.2  tls
1.8.6.2  tls /* The counters of the packet queue. */
1.8.6.2  tls #define	PQCNT_ENQUEUE	0
1.8.6.2  tls #define	PQCNT_DEQUEUE	1
1.8.6.2  tls #define	PQCNT_DROP	2
1.8.6.2  tls #define	PQCNT_NCOUNTERS	3
1.8.6.2  tls
1.8.6.2  tls typedef struct {
1.8.6.2  tls 	uint64_t	count[PQCNT_NCOUNTERS];
1.8.6.2  tls } pktq_counters_t;
1.8.6.2  tls
1.8.6.2  tls /* Special marker value used by pktq_barrier() mechanism. */
1.8.6.2  tls #define	PKTQ_MARKER	((void *)(~0ULL))
1.8.6.2  tls
1.8.6.2  tls /*
1.8.6.2  tls  * The total size of pktqueue_t which depends on the number of CPUs.
1.8.6.2  tls  */
1.8.6.2  tls #define	PKTQUEUE_STRUCT_LEN(ncpu)	\
1.8.6.2  tls     roundup2(offsetof(pktqueue_t, pq_queue[ncpu]), coherency_unit)
1.8.6.2  tls
1.8.6.2  tls pktqueue_t *
1.8.6.2  tls pktq_create(size_t maxlen, void (*intrh)(void *), void *sc)
1.8.6.2  tls {
1.8.6.2  tls 	const u_int sflags = SOFTINT_NET | SOFTINT_MPSAFE | SOFTINT_RCPU;
1.8.6.2  tls 	const size_t len = PKTQUEUE_STRUCT_LEN(ncpu);
1.8.6.2  tls 	pktqueue_t *pq;
1.8.6.2  tls 	percpu_t *pc;
1.8.6.2  tls 	void *sih;
1.8.6.2  tls
1.8.6.2  tls 	if ((pc = percpu_alloc(sizeof(pktq_counters_t))) == NULL) {
1.8.6.2  tls 		return NULL;
1.8.6.2  tls 	}
1.8.6.2  tls 	if ((sih = softint_establish(sflags, intrh, sc)) == NULL) {
1.8.6.2  tls 		percpu_free(pc, sizeof(pktq_counters_t));
1.8.6.2  tls 		return NULL;
1.8.6.2  tls 	}
1.8.6.2  tls
1.8.6.2  tls 	pq = kmem_zalloc(len, KM_SLEEP);
1.8.6.2  tls 	for (u_int i = 0; i < ncpu; i++) {
1.8.6.2  tls 		pq->pq_queue[i] = pcq_create(maxlen, KM_SLEEP);
1.8.6.2  tls 	}
1.8.6.2  tls 	mutex_init(&pq->pq_lock, MUTEX_DEFAULT, IPL_NONE);
1.8.6.2  tls 	pq->pq_maxlen = maxlen;
1.8.6.2  tls 	pq->pq_counters = pc;
1.8.6.2  tls 	pq->pq_sih = sih;
1.8.6.2  tls
1.8.6.2  tls 	return pq;
1.8.6.2  tls }
1.8.6.2  tls
1.8.6.2  tls void
1.8.6.2  tls pktq_destroy(pktqueue_t *pq)
1.8.6.2  tls {
1.8.6.2  tls 	const size_t len = PKTQUEUE_STRUCT_LEN(ncpu);
1.8.6.2  tls
1.8.6.2  tls 	for (u_int i = 0; i < ncpu; i++) {
1.8.6.2  tls 		pcq_t *q = pq->pq_queue[i];
1.8.6.2  tls 		KASSERT(pcq_peek(q) == NULL);
1.8.6.2  tls 		pcq_destroy(q);
1.8.6.2  tls 	}
1.8.6.2  tls 	percpu_free(pq->pq_counters, sizeof(pktq_counters_t));
1.8.6.2  tls 	softint_disestablish(pq->pq_sih);
1.8.6.2  tls 	mutex_destroy(&pq->pq_lock);
1.8.6.2  tls 	kmem_free(pq, len);
1.8.6.2  tls }
1.8.6.2  tls
1.8.6.2  tls /*
1.8.6.2  tls  * - pktq_inc_counter: increment the counter given an ID.
1.8.6.2  tls  * - pktq_collect_counts: handler to sum up the counts from each CPU.
1.8.6.2  tls  * - pktq_getcount: return the effective count given an ID.
1.8.6.2  tls  */
1.8.6.2  tls
1.8.6.2  tls static inline void
1.8.6.2  tls pktq_inc_count(pktqueue_t *pq, u_int i)
1.8.6.2  tls {
1.8.6.2  tls 	percpu_t *pc = pq->pq_counters;
1.8.6.2  tls 	pktq_counters_t *c;
1.8.6.2  tls
1.8.6.2  tls 	c = percpu_getref(pc);
1.8.6.2  tls 	c->count[i]++;
1.8.6.2  tls 	percpu_putref(pc);
1.8.6.2  tls }
1.8.6.2  tls
1.8.6.2  tls static void
1.8.6.2  tls pktq_collect_counts(void *mem, void *arg, struct cpu_info *ci)
1.8.6.2  tls {
1.8.6.2  tls 	const pktq_counters_t *c = mem;
1.8.6.2  tls 	pktq_counters_t *sum = arg;
1.8.6.2  tls
1.8.6.2  tls 	for (u_int i = 0; i < PQCNT_NCOUNTERS; i++) {
1.8.6.2  tls 		sum->count[i] += c->count[i];
1.8.6.2  tls 	}
1.8.6.2  tls }
1.8.6.2  tls
1.8.6.2  tls uint64_t
1.8.6.2  tls pktq_get_count(pktqueue_t *pq, pktq_count_t c)
1.8.6.2  tls {
1.8.6.2  tls 	pktq_counters_t sum;
1.8.6.2  tls
1.8.6.2  tls 	if (c != PKTQ_MAXLEN) {
1.8.6.2  tls 		memset(&sum, 0, sizeof(sum));
1.8.6.2  tls 		percpu_foreach(pq->pq_counters, pktq_collect_counts, &sum);
1.8.6.2  tls 	}
1.8.6.2  tls 	switch (c) {
1.8.6.2  tls 	case PKTQ_NITEMS:
1.8.6.2  tls 		return sum.count[PQCNT_ENQUEUE] - sum.count[PQCNT_DEQUEUE];
1.8.6.2  tls 	case PKTQ_DROPS:
1.8.6.2  tls 		return sum.count[PQCNT_DROP];
1.8.6.2  tls 	case PKTQ_MAXLEN:
1.8.6.2  tls 		return pq->pq_maxlen;
1.8.6.2  tls 	}
1.8.6.2  tls 	return 0;
1.8.6.2  tls }
1.8.6.2  tls
1.8.6.2  tls uint32_t
1.8.6.2  tls pktq_rps_hash(const struct mbuf *m __unused)
1.8.6.2  tls {
1.8.6.2  tls 	/*
1.8.6.2  tls 	 * XXX: No distribution yet; the softnet_lock contention
1.8.6.2  tls 	 * XXX: must be eliminated first.
1.8.6.2  tls 	 */
1.8.6.2  tls 	return 0;
1.8.6.2  tls }
1.8.6.2  tls
1.8.6.2  tls /*
1.8.6.2  tls  * pktq_enqueue: inject the packet into the end of the queue.
1.8.6.2  tls  *
1.8.6.2  tls  * => Must be called from the interrupt or with the preemption disabled.
1.8.6.2  tls  * => Consumes the packet and returns true on success.
1.8.6.2  tls  * => Returns false on failure; caller is responsible to free the packet.
1.8.6.2  tls  */
1.8.6.2  tls bool
1.8.6.2  tls pktq_enqueue(pktqueue_t *pq, struct mbuf *m, const u_int hash __unused)
1.8.6.2  tls {
1.8.6.2  tls #if defined(_RUMPKERNEL) || defined(_RUMP_NATIVE_ABI)
1.8.6.2  tls 	const unsigned cpuid = curcpu()->ci_index;
1.8.6.2  tls #else
1.8.6.2  tls 	const unsigned cpuid = hash % ncpu;
1.8.6.2  tls #endif
1.8.6.2  tls
1.8.6.2  tls 	KASSERT(kpreempt_disabled());
1.8.6.2  tls
1.8.6.2  tls 	if (__predict_false(!pcq_put(pq->pq_queue[cpuid], m))) {
1.8.6.2  tls 		pktq_inc_count(pq, PQCNT_DROP);
1.8.6.2  tls 		return false;
1.8.6.2  tls 	}
1.8.6.2  tls 	softint_schedule_cpu(pq->pq_sih, cpu_lookup(cpuid));
1.8.6.2  tls 	pktq_inc_count(pq, PQCNT_ENQUEUE);
1.8.6.2  tls 	return true;
1.8.6.2  tls }
1.8.6.2  tls
1.8.6.2  tls /*
1.8.6.2  tls  * pktq_dequeue: take a packet from the queue.
1.8.6.2  tls  *
1.8.6.2  tls  * => Must be called with preemption disabled.
1.8.6.2  tls  * => Must ensure there are not concurrent dequeue calls.
1.8.6.2  tls  */
1.8.6.2  tls struct mbuf *
1.8.6.2  tls pktq_dequeue(pktqueue_t *pq)
1.8.6.2  tls {
1.8.6.2  tls 	const struct cpu_info *ci = curcpu();
1.8.6.2  tls 	const unsigned cpuid = cpu_index(ci);
1.8.6.2  tls 	struct mbuf *m;
1.8.6.2  tls
1.8.6.2  tls 	m = pcq_get(pq->pq_queue[cpuid]);
1.8.6.2  tls 	if (__predict_false(m == PKTQ_MARKER)) {
1.8.6.2  tls 		/* Note the marker entry. */
1.8.6.2  tls 		atomic_inc_uint(&pq->pq_barrier);
1.8.6.2  tls 		return NULL;
1.8.6.2  tls 	}
1.8.6.2  tls 	if (__predict_true(m != NULL)) {
1.8.6.2  tls 		pktq_inc_count(pq, PQCNT_DEQUEUE);
1.8.6.2  tls 	}
1.8.6.2  tls 	return m;
1.8.6.2  tls }
1.8.6.2  tls
1.8.6.2  tls /*
1.8.6.2  tls  * pktq_barrier: waits for a grace period when all packets enqueued at
1.8.6.2  tls  * the moment of calling this routine will be processed.  This is used
1.8.6.2  tls  * to ensure that e.g. packets referencing some interface were drained.
1.8.6.2  tls  */
1.8.6.2  tls void
1.8.6.2  tls pktq_barrier(pktqueue_t *pq)
1.8.6.2  tls {
1.8.6.2  tls 	u_int pending = 0;
1.8.6.2  tls
1.8.6.2  tls 	mutex_enter(&pq->pq_lock);
1.8.6.2  tls 	KASSERT(pq->pq_barrier == 0);
1.8.6.2  tls
1.8.6.2  tls 	for (u_int i = 0; i < ncpu; i++) {
1.8.6.2  tls 		pcq_t *q = pq->pq_queue[i];
1.8.6.2  tls
1.8.6.2  tls 		/* If the queue is empty - nothing to do. */
1.8.6.2  tls 		if (pcq_peek(q) == NULL) {
1.8.6.2  tls 			continue;
1.8.6.2  tls 		}
1.8.6.2  tls 		/* Otherwise, put the marker and entry. */
1.8.6.2  tls 		while (!pcq_put(q, PKTQ_MARKER)) {
1.8.6.2  tls 			kpause("pktqsync", false, 1, NULL);
1.8.6.2  tls 		}
1.8.6.2  tls 		kpreempt_disable();
1.8.6.2  tls 		softint_schedule_cpu(pq->pq_sih, cpu_lookup(i));
1.8.6.2  tls 		kpreempt_enable();
1.8.6.2  tls 		pending++;
1.8.6.2  tls 	}
1.8.6.2  tls
1.8.6.2  tls 	/* Wait for each queue to process the markers. */
1.8.6.2  tls 	while (pq->pq_barrier != pending) {
1.8.6.2  tls 		kpause("pktqsync", false, 1, NULL);
1.8.6.2  tls 	}
1.8.6.2  tls 	pq->pq_barrier = 0;
1.8.6.2  tls 	mutex_exit(&pq->pq_lock);
1.8.6.2  tls }
1.8.6.2  tls
1.8.6.2  tls /*
1.8.6.2  tls  * pktq_flush: free mbufs in all queues.
1.8.6.2  tls  *
1.8.6.2  tls  * => The caller must ensure there are no concurrent writers or flush calls.
1.8.6.2  tls  */
1.8.6.2  tls void
1.8.6.2  tls pktq_flush(pktqueue_t *pq)
1.8.6.2  tls {
1.8.6.2  tls 	struct mbuf *m;
1.8.6.2  tls
1.8.6.2  tls 	for (u_int i = 0; i < ncpu; i++) {
1.8.6.2  tls 		while ((m = pcq_get(pq->pq_queue[i])) != NULL) {
1.8.6.2  tls 			pktq_inc_count(pq, PQCNT_DEQUEUE);
1.8.6.2  tls 			m_freem(m);
1.8.6.2  tls 		}
1.8.6.2  tls 	}
1.8.6.2  tls }
1.8.6.2  tls
1.8.6.2  tls /*
1.8.6.2  tls  * pktq_set_maxlen: create per-CPU queues using a new size and replace
1.8.6.2  tls  * the existing queues without losing any packets.
1.8.6.2  tls  */
1.8.6.2  tls int
1.8.6.2  tls pktq_set_maxlen(pktqueue_t *pq, size_t maxlen)
1.8.6.2  tls {
1.8.6.2  tls 	const u_int slotbytes = ncpu * sizeof(pcq_t *);
1.8.6.2  tls 	pcq_t **qs;
1.8.6.2  tls
1.8.6.2  tls 	if (!maxlen || maxlen > PCQ_MAXLEN)
1.8.6.2  tls 		return EINVAL;
1.8.6.2  tls 	if (pq->pq_maxlen == maxlen)
1.8.6.2  tls 		return 0;
1.8.6.2  tls
1.8.6.2  tls 	/* First, allocate the new queues and replace them. */
1.8.6.2  tls 	qs = kmem_zalloc(slotbytes, KM_SLEEP);
1.8.6.2  tls 	for (u_int i = 0; i < ncpu; i++) {
1.8.6.2  tls 		qs[i] = pcq_create(maxlen, KM_SLEEP);
1.8.6.2  tls 	}
1.8.6.2  tls 	mutex_enter(&pq->pq_lock);
1.8.6.2  tls 	for (u_int i = 0; i < ncpu; i++) {
1.8.6.2  tls 		/* Swap: store of a word is atomic. */
1.8.6.2  tls 		pcq_t *q = pq->pq_queue[i];
1.8.6.2  tls 		pq->pq_queue[i] = qs[i];
1.8.6.2  tls 		qs[i] = q;
1.8.6.2  tls 	}
1.8.6.2  tls 	pq->pq_maxlen = maxlen;
1.8.6.2  tls 	mutex_exit(&pq->pq_lock);
1.8.6.2  tls
1.8.6.2  tls 	/*
1.8.6.2  tls 	 * At this point, the new packets are flowing into the new
1.8.6.2  tls 	 * queues.  However, the old queues may have some packets
1.8.6.2  tls 	 * present which are no longer being processed.  We are going
1.8.6.2  tls 	 * to re-enqueue them.  This may change the order of packet
1.8.6.2  tls 	 * arrival, but it is not considered an issue.
1.8.6.2  tls 	 *
1.8.6.2  tls 	 * There may be in-flight interrupts calling pktq_dequeue()
1.8.6.2  tls 	 * which reference the old queues.  Issue a barrier to ensure
1.8.6.2  tls 	 * that we are going to be the only pcq_get() callers on the
1.8.6.2  tls 	 * old queues.
1.8.6.2  tls 	 */
1.8.6.2  tls 	pktq_barrier(pq);
1.8.6.2  tls
1.8.6.2  tls 	for (u_int i = 0; i < ncpu; i++) {
1.8.6.2  tls 		struct mbuf *m;
1.8.6.2  tls
1.8.6.2  tls 		while ((m = pcq_get(qs[i])) != NULL) {
1.8.6.2  tls 			while (!pcq_put(pq->pq_queue[i], m)) {
1.8.6.2  tls 				kpause("pktqrenq", false, 1, NULL);
1.8.6.2  tls 			}
1.8.6.2  tls 		}
1.8.6.2  tls 		pcq_destroy(qs[i]);
1.8.6.2  tls 	}
1.8.6.2  tls
1.8.6.2  tls 	/* Well, that was fun. */
1.8.6.2  tls 	kmem_free(qs, slotbytes);
1.8.6.2  tls 	return 0;
1.8.6.2  tls }
1.8.6.2  tls
1.8.6.2  tls int
1.8.6.2  tls sysctl_pktq_maxlen(SYSCTLFN_ARGS, pktqueue_t *pq)
1.8.6.2  tls {
1.8.6.2  tls 	u_int nmaxlen = pktq_get_count(pq, PKTQ_MAXLEN);
1.8.6.2  tls 	struct sysctlnode node = *rnode;
1.8.6.2  tls 	int error;
1.8.6.2  tls
1.8.6.2  tls 	node.sysctl_data = &nmaxlen;
1.8.6.2  tls 	error = sysctl_lookup(SYSCTLFN_CALL(&node));
1.8.6.2  tls 	if (error || newp == NULL)
1.8.6.2  tls 		return error;
1.8.6.2  tls 	return pktq_set_maxlen(pq, nmaxlen);
1.8.6.2  tls }
1.8.6.2  tls
1.8.6.2  tls int
1.8.6.2  tls sysctl_pktq_count(SYSCTLFN_ARGS, pktqueue_t *pq, u_int count_id)
1.8.6.2  tls {
1.8.6.2  tls 	int count = pktq_get_count(pq, count_id);
1.8.6.2  tls 	struct sysctlnode node = *rnode;
1.8.6.2  tls 	node.sysctl_data = &count;
1.8.6.2  tls 	return sysctl_lookup(SYSCTLFN_CALL(&node));
1.8.6.2  tls }