/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2007 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * IP interface to squeues. * * IP creates an squeue instance for each CPU. The squeue pointer is saved in * cpu_squeue field of the cpu structure. Each squeue is associated with a * connection instance (conn_t). * * For CPUs available at system startup time the squeue creation and association * with CPU happens at MP initialization time. For CPUs added during dynamic * reconfiguration, the initialization happens when the new CPU is configured in * the system. The squeue is chosen using IP_SQUEUE_GET macro which will either * return per-CPU squeue or random squeue based on the ip_squeue_fanout * variable. * * There are two modes of associating connection with squeues. The first mode * associates each connection with the CPU that creates the connection (either * during open time or during accept time). The second mode associates each * connection with a random CPU, effectively distributing load over all CPUs * and all squeues in the system. The mode is controlled by the * ip_squeue_fanout variable. * * NOTE: The fact that there is an association between each connection and * squeue and squeue and CPU does not mean that each connection is always * processed on this CPU and on this CPU only. Any thread calling squeue_enter() * may process the connection on whatever CPU it is scheduled. The squeue to CPU * binding is only relevant for the worker thread. * * The list of all created squeues is kept in squeue_set structure. This list is * used when ip_squeue_fanout is set and the load is distributed across all * squeues. * * INTERFACE: * * squeue_t *ip_squeue_get(hint) * * Find an squeue based on the 'hint' value. The hint is used as an index * in the array of IP squeues available. The way hint is computed may * affect the effectiveness of the squeue distribution. Currently squeues * are assigned in round-robin fashion using lbolt as a hint. * * * DR Notes * ======== * * The ip_squeue_init() registers a call-back function with the CPU DR * subsystem using register_cpu_setup_func(). The call-back function does two * things: * * o When the CPU is going off-line or unconfigured, the worker thread is * unbound from the CPU. This allows the CPU unconfig code to move it to * another CPU. * * o When the CPU is going online, it creates a new squeue for this CPU if * necessary and binds the squeue worker thread to this CPU. * * TUNEBALES: * * ip_squeue_bind: if set to 1 each squeue worker thread is bound to the CPU * associated with an squeue instance. * * ip_squeue_profile: if set to 1 squeue profiling is enabled. NOTE: squeue.c * should be compiled with SQUEUE_PROFILE enabled for this variable to have * an impact. * * ip_squeue_fanout: if set to 1 use ip_squeue_get() to find an squeue, * otherwise get it from CPU->cpu_squeue. * * ip_squeue_bind, ip_squeue_profile and ip_squeue_fanout can be accessed and * changed using ndd on /dev/tcp or /dev/ip. * * ip_squeue_worker_wait: global value for the sq_wait field for all squeues * created. This is the time squeue code waits before waking up the worker * thread after queuing a request. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* * We allow multiple NICs to bind to the same CPU but want to preserve 1 <-> 1 * mapping between squeue and NIC (or Rx ring) for performance reasons so * each squeue can uniquely own a NIC or a Rx ring and do polling * (PSARC 2004/630). So we allow up to MAX_SQUEUES_PER_CPU squeues per CPU. * We start by creating MIN_SQUEUES_PER_CPU squeues per CPU but more squeues * can be created dynamically as needed. */ #define MAX_SQUEUES_PER_CPU 32 #define MIN_SQUEUES_PER_CPU 1 uint_t ip_squeues_per_cpu = MIN_SQUEUES_PER_CPU; #define IP_NUM_SOFT_RINGS 2 uint_t ip_soft_rings_cnt = IP_NUM_SOFT_RINGS; /* * List of all created squeue sets. The size is protected by cpu_lock */ squeue_set_t **sqset_global_list; uint_t sqset_global_size; int ip_squeue_bind = B_TRUE; int ip_squeue_profile = B_TRUE; static void (*ip_squeue_create_callback)(squeue_t *) = NULL; /* * ip_squeue_worker_wait: global value for the sq_wait field for all squeues * created. This is the time squeue code waits before waking up the worker * thread after queuing a request. */ uint_t ip_squeue_worker_wait = 10; static squeue_set_t *ip_squeue_set_create(cpu_t *, boolean_t); static int ip_squeue_cpu_setup(cpu_setup_t, int, void *); static void ip_squeue_set_bind(squeue_set_t *); static void ip_squeue_set_unbind(squeue_set_t *); static squeue_t *ip_find_unused_squeue(squeue_set_t *, cpu_t *, boolean_t); #define CPU_ISON(c) (c != NULL && CPU_ACTIVE(c) && (c->cpu_flags & CPU_EXISTS)) /* * Create squeue set containing ip_squeues_per_cpu number of squeues * for this CPU and bind them all to the CPU. */ static squeue_set_t * ip_squeue_set_create(cpu_t *cp, boolean_t reuse) { int i; squeue_set_t *sqs; squeue_t *sqp; char sqname[64]; processorid_t id = cp->cpu_id; if (reuse) { int i; /* * We may already have an squeue created for this CPU. Try to * find one and reuse it if possible. */ for (i = 0; i < sqset_global_size; i++) { sqs = sqset_global_list[i]; if (id == sqs->sqs_bind) return (sqs); } } sqs = kmem_zalloc(sizeof (squeue_set_t) + (sizeof (squeue_t *) * MAX_SQUEUES_PER_CPU), KM_SLEEP); mutex_init(&sqs->sqs_lock, NULL, MUTEX_DEFAULT, NULL); sqs->sqs_list = (squeue_t **)&sqs[1]; sqs->sqs_max_size = MAX_SQUEUES_PER_CPU; sqs->sqs_bind = id; for (i = 0; i < ip_squeues_per_cpu; i++) { bzero(sqname, sizeof (sqname)); (void) snprintf(sqname, sizeof (sqname), "ip_squeue_cpu_%d/%d/%d", cp->cpu_seqid, cp->cpu_id, i); sqp = squeue_create(sqname, id, ip_squeue_worker_wait, minclsyspri); /* * The first squeue in each squeue_set is the DEFAULT * squeue. */ sqp->sq_state |= SQS_DEFAULT; ASSERT(sqp != NULL); squeue_profile_enable(sqp); sqs->sqs_list[sqs->sqs_size++] = sqp; if (ip_squeue_create_callback != NULL) ip_squeue_create_callback(sqp); } if (ip_squeue_bind && cpu_is_online(cp)) ip_squeue_set_bind(sqs); sqset_global_list[sqset_global_size++] = sqs; ASSERT(sqset_global_size <= NCPU); return (sqs); } /* * Initialize IP squeues. */ void ip_squeue_init(void (*callback)(squeue_t *)) { int i; ASSERT(sqset_global_list == NULL); if (ip_squeues_per_cpu < MIN_SQUEUES_PER_CPU) ip_squeues_per_cpu = MIN_SQUEUES_PER_CPU; else if (ip_squeues_per_cpu > MAX_SQUEUES_PER_CPU) ip_squeues_per_cpu = MAX_SQUEUES_PER_CPU; ip_squeue_create_callback = callback; squeue_init(); sqset_global_list = kmem_zalloc(sizeof (squeue_set_t *) * NCPU, KM_SLEEP); sqset_global_size = 0; mutex_enter(&cpu_lock); /* Create squeue for each active CPU available */ for (i = 0; i < NCPU; i++) { cpu_t *cp = cpu[i]; if (CPU_ISON(cp) && cp->cpu_squeue_set == NULL) { cp->cpu_squeue_set = ip_squeue_set_create(cp, B_FALSE); } } register_cpu_setup_func(ip_squeue_cpu_setup, NULL); mutex_exit(&cpu_lock); if (ip_squeue_profile) squeue_profile_start(); } /* * Get squeue_t structure based on index. * Since the squeue list can only grow, no need to grab any lock. */ squeue_t * ip_squeue_random(uint_t index) { squeue_set_t *sqs; sqs = sqset_global_list[index % sqset_global_size]; return (sqs->sqs_list[index % sqs->sqs_size]); } /* ARGSUSED */ void ip_squeue_clean(void *arg1, mblk_t *mp, void *arg2) { squeue_t *sqp = arg2; ill_rx_ring_t *ring = sqp->sq_rx_ring; ill_t *ill; ASSERT(sqp != NULL); if (ring == NULL) { return; } /* * Clean up squeue */ mutex_enter(&sqp->sq_lock); sqp->sq_state &= ~(SQS_ILL_BOUND|SQS_POLL_CAPAB); sqp->sq_rx_ring = NULL; mutex_exit(&sqp->sq_lock); ill = ring->rr_ill; if (ill->ill_capabilities & ILL_CAPAB_SOFT_RING) { ASSERT(ring->rr_handle != NULL); ill->ill_dls_capab->ill_dls_unbind(ring->rr_handle); } /* * Cleanup the ring */ ring->rr_blank = NULL; ring->rr_handle = NULL; ring->rr_sqp = NULL; /* * Signal ill that cleanup is done */ mutex_enter(&ill->ill_lock); ring->rr_ring_state = ILL_RING_FREE; cv_signal(&ill->ill_cv); mutex_exit(&ill->ill_lock); } typedef struct ip_taskq_arg { ill_t *ip_taskq_ill; ill_rx_ring_t *ip_taskq_ill_rx_ring; cpu_t *ip_taskq_cpu; } ip_taskq_arg_t; /* * Do a Rx ring to squeue binding. Find a unique squeue that is not * managing a receive ring. If no such squeue exists, dynamically * create a new one in the squeue set. * * The function runs via the system taskq. The ill passed as an * argument can't go away since we hold a ref. The lock order is * ill_lock -> sqs_lock -> sq_lock. * * If we are binding a Rx ring to a squeue attached to the offline CPU, * no need to check that because squeues are never destroyed once * created. */ /* ARGSUSED */ static void ip_squeue_extend(void *arg) { ip_taskq_arg_t *sq_arg = (ip_taskq_arg_t *)arg; ill_t *ill = sq_arg->ip_taskq_ill; ill_rx_ring_t *ill_rx_ring = sq_arg->ip_taskq_ill_rx_ring; cpu_t *intr_cpu = sq_arg->ip_taskq_cpu; squeue_set_t *sqs; squeue_t *sqp = NULL; ASSERT(ill != NULL); ASSERT(ill_rx_ring != NULL); kmem_free(arg, sizeof (ip_taskq_arg_t)); /* * Make sure the CPU that originally took the interrupt still * exists. */ if (!CPU_ISON(intr_cpu)) intr_cpu = CPU; sqs = intr_cpu->cpu_squeue_set; /* * If this ill represents link aggregation, then there might be * multiple NICs trying to register them selves at the same time * and in order to ensure that test and assignment of free rings * is sequential, we need to hold the ill_lock. */ mutex_enter(&ill->ill_lock); sqp = ip_find_unused_squeue(sqs, intr_cpu, B_FALSE); if (sqp == NULL) { /* * We hit the max limit of squeues allowed per CPU. * Assign this rx_ring to DEFAULT squeue of the * interrupted CPU but the squeue will not manage * the ring. Also print a warning. */ cmn_err(CE_NOTE, "ip_squeue_extend: CPU/sqset = %d/%p already " "has max number of squeues. System performance might " "become suboptimal\n", sqs->sqs_bind, (void *)sqs); /* the first squeue in the list is the default squeue */ sqp = sqs->sqs_list[0]; ASSERT(sqp != NULL); ill_rx_ring->rr_sqp = sqp; ill_rx_ring->rr_ring_state = ILL_RING_INUSE; mutex_exit(&ill->ill_lock); ill_waiter_dcr(ill); return; } ASSERT(MUTEX_HELD(&sqp->sq_lock)); sqp->sq_rx_ring = ill_rx_ring; ill_rx_ring->rr_sqp = sqp; ill_rx_ring->rr_ring_state = ILL_RING_INUSE; sqp->sq_state |= (SQS_ILL_BOUND|SQS_POLL_CAPAB); mutex_exit(&sqp->sq_lock); mutex_exit(&ill->ill_lock); /* ill_waiter_dcr will also signal any waiters on ill_ring_state */ ill_waiter_dcr(ill); } /* * Do a Rx ring to squeue binding. Find a unique squeue that is not * managing a receive ring. If no such squeue exists, dynamically * create a new one in the squeue set. * * The function runs via the system taskq. The ill passed as an * argument can't go away since we hold a ref. The lock order is * ill_lock -> sqs_lock -> sq_lock. * * If we are binding a Rx ring to a squeue attached to the offline CPU, * no need to check that because squeues are never destroyed once * created. */ /* ARGSUSED */ static void ip_squeue_soft_ring_affinity(void *arg) { ip_taskq_arg_t *sq_arg = (ip_taskq_arg_t *)arg; ill_t *ill = sq_arg->ip_taskq_ill; ill_dls_capab_t *ill_soft_ring = ill->ill_dls_capab; ill_rx_ring_t *ill_rx_ring = sq_arg->ip_taskq_ill_rx_ring; cpu_t *intr_cpu = sq_arg->ip_taskq_cpu; cpu_t *bind_cpu; int cpu_id = intr_cpu->cpu_id; int min_cpu_id, max_cpu_id; boolean_t enough_uniq_cpus = B_FALSE; boolean_t enough_cpus = B_FALSE; squeue_set_t *sqs, *last_sqs; squeue_t *sqp = NULL; int i, j; ASSERT(ill != NULL); kmem_free(arg, sizeof (ip_taskq_arg_t)); /* * Make sure the CPU that originally took the interrupt still * exists. */ if (!CPU_ISON(intr_cpu)) { intr_cpu = CPU; cpu_id = intr_cpu->cpu_id; } /* * If this ill represents link aggregation, then there might be * multiple NICs trying to register them selves at the same time * and in order to ensure that test and assignment of free rings * is sequential, we need to hold the ill_lock. */ mutex_enter(&ill->ill_lock); if (!(ill->ill_state_flags & ILL_SOFT_RING_ASSIGN)) { mutex_exit(&ill->ill_lock); return; } /* * We need to fanout the interrupts from the NIC. We do that by * telling the driver underneath to create soft rings and use * worker threads (if the driver advertized SOFT_RING capability) * Its still a big performance win to if we can fanout to the * threads on the same core that is taking interrupts. * * Since we don't know the interrupt to CPU binding, we don't * assign any squeues or affinity to worker threads in the NIC. * At the time of the first interrupt, we know which CPU is * taking interrupts and try to find other threads on the same * core. Assuming, ip_threads_per_cpu is correct and cpus are * numbered sequentially for each core (XXX need something better * than this in future), find the lowest number and highest * number thread for that core. * * If we have one more thread per core than number of soft rings, * then don't assign any worker threads to the H/W thread (cpu) * taking interrupts (capability negotiation tries to ensure this) * * If the number of threads per core are same as the number of * soft rings, then assign the worker affinity and squeue to * the same cpu. * * Otherwise, just fanout to higher number CPUs starting from * the interrupted CPU. */ min_cpu_id = (cpu_id / ip_threads_per_cpu) * ip_threads_per_cpu; max_cpu_id = min_cpu_id + ip_threads_per_cpu; /* * Quickly check if there are enough CPUs present for fanout * and also max_cpu_id is less than the id of the active CPU. * We use the cpu_id stored in the last squeue_set to get * an idea. The scheme is by no means perfect since it doesn't * take into account CPU DR operations and the fact that * interrupts themselves might change. An ideal scenario * would be to ensure that interrupts run cpus by themselves * and worker threads never have affinity to those CPUs. If * the interrupts move to CPU which had a worker thread, it * should be changed. Probably callbacks similar to CPU offline * are needed to make it work perfectly. */ last_sqs = sqset_global_list[sqset_global_size - 1]; if (ip_threads_per_cpu <= ncpus && max_cpu_id <= last_sqs->sqs_bind) { if ((max_cpu_id - min_cpu_id) > ill_soft_ring->ill_dls_soft_ring_cnt) enough_uniq_cpus = B_TRUE; else if ((max_cpu_id - min_cpu_id) >= ill_soft_ring->ill_dls_soft_ring_cnt) enough_cpus = B_TRUE; } j = 0; for (i = 0; i < (ill_soft_ring->ill_dls_soft_ring_cnt + j); i++) { if (enough_uniq_cpus) { if ((min_cpu_id + i) == cpu_id) { j++; continue; } bind_cpu = cpu[min_cpu_id + i]; } else if (enough_cpus) { bind_cpu = cpu[min_cpu_id + i]; } else { /* bind_cpu = cpu[(cpu_id + i) % last_sqs->sqs_bind]; */ bind_cpu = cpu[(cpu_id + i) % ncpus]; } /* * Check if the CPU actually exist and active. If not, * use the interrupted CPU. ip_find_unused_squeue() will * find the right CPU to fanout anyway. */ if (!CPU_ISON(bind_cpu)) bind_cpu = intr_cpu; sqs = bind_cpu->cpu_squeue_set; ASSERT(sqs != NULL); ill_rx_ring = &ill_soft_ring->ill_ring_tbl[i - j]; sqp = ip_find_unused_squeue(sqs, bind_cpu, B_TRUE); if (sqp == NULL) { /* * We hit the max limit of squeues allowed per CPU. * Assign this rx_ring to DEFAULT squeue of the * interrupted CPU but thesqueue will not manage * the ring. Also print a warning. */ cmn_err(CE_NOTE, "ip_squeue_soft_ring: CPU/sqset = " "%d/%p already has max number of squeues. System " "performance might become suboptimal\n", sqs->sqs_bind, (void *)sqs); /* the first squeue in the list is the default squeue */ sqp = intr_cpu->cpu_squeue_set->sqs_list[0]; ASSERT(sqp != NULL); ill_rx_ring->rr_sqp = sqp; ill_rx_ring->rr_ring_state = ILL_RING_INUSE; continue; } ASSERT(MUTEX_HELD(&sqp->sq_lock)); ill_rx_ring->rr_sqp = sqp; sqp->sq_rx_ring = ill_rx_ring; ill_rx_ring->rr_ring_state = ILL_RING_INUSE; sqp->sq_state |= SQS_ILL_BOUND; /* assign affinity to soft ring */ if (ip_squeue_bind && (sqp->sq_state & SQS_BOUND)) { ill_soft_ring->ill_dls_bind(ill_rx_ring->rr_handle, sqp->sq_bind); } mutex_exit(&sqp->sq_lock); } mutex_exit(&ill->ill_lock); ill_soft_ring->ill_dls_change_status(ill_soft_ring->ill_tx_handle, SOFT_RING_FANOUT); mutex_enter(&ill->ill_lock); ill->ill_state_flags &= ~ILL_SOFT_RING_ASSIGN; mutex_exit(&ill->ill_lock); /* ill_waiter_dcr will also signal any waiters on ill_ring_state */ ill_waiter_dcr(ill); } /* ARGSUSED */ void ip_soft_ring_assignment(ill_t *ill, ill_rx_ring_t *ip_ring, mblk_t *mp_chain, struct mac_header_info_s *mhip) { ip_taskq_arg_t *taskq_arg; boolean_t refheld; ASSERT(servicing_interrupt()); mutex_enter(&ill->ill_lock); if (!(ill->ill_state_flags & ILL_SOFT_RING_ASSIGN)) { taskq_arg = (ip_taskq_arg_t *) kmem_zalloc(sizeof (ip_taskq_arg_t), KM_NOSLEEP); if (taskq_arg == NULL) goto out; taskq_arg->ip_taskq_ill = ill; taskq_arg->ip_taskq_ill_rx_ring = NULL; taskq_arg->ip_taskq_cpu = CPU; /* * Set ILL_SOFT_RING_ASSIGN flag. We don't want * the next interrupt to schedule a task for calling * ip_squeue_soft_ring_affinity(); */ ill->ill_state_flags |= ILL_SOFT_RING_ASSIGN; } else { mutex_exit(&ill->ill_lock); goto out; } mutex_exit(&ill->ill_lock); refheld = ill_waiter_inc(ill); if (refheld) { if (taskq_dispatch(system_taskq, ip_squeue_soft_ring_affinity, taskq_arg, TQ_NOSLEEP)) goto out; /* release ref on ill if taskq dispatch fails */ ill_waiter_dcr(ill); } /* * Turn on CAPAB_SOFT_RING so that affinity assignment * can be tried again later. */ mutex_enter(&ill->ill_lock); ill->ill_state_flags &= ~ILL_SOFT_RING_ASSIGN; mutex_exit(&ill->ill_lock); kmem_free(taskq_arg, sizeof (ip_taskq_arg_t)); out: ip_input(ill, NULL, mp_chain, mhip); } static squeue_t * ip_find_unused_squeue(squeue_set_t *sqs, cpu_t *bind_cpu, boolean_t fanout) { int i; squeue_set_t *best_sqs = NULL; squeue_set_t *curr_sqs = NULL; int min_sq = 0; squeue_t *sqp = NULL; char sqname[64]; /* * If fanout is set and the passed squeue_set already has some * squeues which are managing the NICs, try to find squeues on * unused CPU. */ if (sqs->sqs_size > 1 && fanout) { /* * First check to see if any squeue on the CPU passed * is managing a NIC. */ for (i = 0; i < sqs->sqs_size; i++) { mutex_enter(&sqs->sqs_list[i]->sq_lock); if ((sqs->sqs_list[i]->sq_state & SQS_ILL_BOUND) && !(sqs->sqs_list[i]->sq_state & SQS_DEFAULT)) { mutex_exit(&sqs->sqs_list[i]->sq_lock); break; } mutex_exit(&sqs->sqs_list[i]->sq_lock); } if (i != sqs->sqs_size) { best_sqs = sqset_global_list[sqset_global_size - 1]; min_sq = best_sqs->sqs_size; for (i = sqset_global_size - 2; i >= 0; i--) { curr_sqs = sqset_global_list[i]; if (curr_sqs->sqs_size < min_sq) { best_sqs = curr_sqs; min_sq = curr_sqs->sqs_size; } } ASSERT(best_sqs != NULL); sqs = best_sqs; bind_cpu = cpu[sqs->sqs_bind]; } } mutex_enter(&sqs->sqs_lock); for (i = 0; i < sqs->sqs_size; i++) { mutex_enter(&sqs->sqs_list[i]->sq_lock); if ((sqs->sqs_list[i]->sq_state & (SQS_DEFAULT|SQS_ILL_BOUND)) == 0) { sqp = sqs->sqs_list[i]; break; } mutex_exit(&sqs->sqs_list[i]->sq_lock); } if (sqp == NULL) { /* Need to create a new squeue */ if (sqs->sqs_size == sqs->sqs_max_size) { /* * Reached the max limit for squeue * we can allocate on this CPU. */ mutex_exit(&sqs->sqs_lock); return (NULL); } bzero(sqname, sizeof (sqname)); (void) snprintf(sqname, sizeof (sqname), "ip_squeue_cpu_%d/%d/%d", bind_cpu->cpu_seqid, bind_cpu->cpu_id, sqs->sqs_size); sqp = squeue_create(sqname, bind_cpu->cpu_id, ip_squeue_worker_wait, minclsyspri); ASSERT(sqp != NULL); squeue_profile_enable(sqp); sqs->sqs_list[sqs->sqs_size++] = sqp; if (ip_squeue_create_callback != NULL) ip_squeue_create_callback(sqp); mutex_enter(&cpu_lock); if (ip_squeue_bind && cpu_is_online(bind_cpu)) { squeue_bind(sqp, -1); } mutex_exit(&cpu_lock); mutex_enter(&sqp->sq_lock); } mutex_exit(&sqs->sqs_lock); ASSERT(sqp != NULL); return (sqp); } /* * Find the squeue assigned to manage this Rx ring. If the Rx ring is not * owned by a squeue yet, do the assignment. When the NIC registers it * Rx rings with IP, we don't know where the interrupts will land and * hence we need to wait till this point to do the assignment. */ squeue_t * ip_squeue_get(ill_rx_ring_t *ill_rx_ring) { squeue_t *sqp; ill_t *ill; int interrupt; ip_taskq_arg_t *taskq_arg; boolean_t refheld; if (ill_rx_ring == NULL) return (IP_SQUEUE_GET(lbolt)); sqp = ill_rx_ring->rr_sqp; /* * Do a quick check. If it's not NULL, we are done. * Squeues are never destroyed so worse we will bind * this connection to a suboptimal squeue. * * This is the fast path case. */ if (sqp != NULL) return (sqp); ill = ill_rx_ring->rr_ill; ASSERT(ill != NULL); interrupt = servicing_interrupt(); taskq_arg = (ip_taskq_arg_t *)kmem_zalloc(sizeof (ip_taskq_arg_t), KM_NOSLEEP); mutex_enter(&ill->ill_lock); /* * Check sqp under the lock again for atomicity. Possible race with * a previously scheduled ip_squeue_get -> ip_squeue_extend. * Do the ring to squeue binding only if we are in interrupt context * AND the ring is not already bound AND there is no one else trying * the bind already. */ sqp = ill_rx_ring->rr_sqp; if (sqp != NULL || !interrupt || ill_rx_ring->rr_ring_state != ILL_RING_INUSE || taskq_arg == NULL) { /* * Note that the ring might get bound once we drop the lock * below, if a previous request is in progress i.e. if the ring * state is ILL_RING_INPROC. The incoming connection on whose * behalf we are currently here might get a suboptimal squeue * via the call to IP_SQUEUE_GET below, but there is no * correctness issue. */ mutex_exit(&ill->ill_lock); if (taskq_arg != NULL) kmem_free(taskq_arg, sizeof (ip_taskq_arg_t)); if (sqp != NULL) return (sqp); return (IP_SQUEUE_GET(lbolt)); } /* * No sqp assigned yet. Can't really do that in interrupt * context. Assign the default sqp to this connection and * trigger creation of new sqp and binding it to this ring * via taskq. Need to make sure ill stays around. */ taskq_arg->ip_taskq_ill = ill; taskq_arg->ip_taskq_ill_rx_ring = ill_rx_ring; taskq_arg->ip_taskq_cpu = CPU; ill_rx_ring->rr_ring_state = ILL_RING_INPROC; mutex_exit(&ill->ill_lock); refheld = ill_waiter_inc(ill); if (refheld) { if (taskq_dispatch(system_taskq, ip_squeue_extend, taskq_arg, TQ_NOSLEEP) != NULL) { return (IP_SQUEUE_GET(lbolt)); } } /* * The ill is closing and we could not get a reference on the ill OR * taskq_dispatch failed probably due to memory allocation failure. * We will try again next time. */ mutex_enter(&ill->ill_lock); ill_rx_ring->rr_ring_state = ILL_RING_INUSE; mutex_exit(&ill->ill_lock); kmem_free(taskq_arg, sizeof (ip_taskq_arg_t)); if (refheld) ill_waiter_dcr(ill); return (IP_SQUEUE_GET(lbolt)); } /* * NDD hooks for setting ip_squeue_xxx tuneables. */ /* ARGSUSED */ int ip_squeue_bind_set(queue_t *q, mblk_t *mp, char *value, caddr_t addr, cred_t *cr) { int *bind_enabled = (int *)addr; long new_value; int i; if (ddi_strtol(value, NULL, 10, &new_value) != 0) return (EINVAL); if (ip_squeue_bind == new_value) return (0); *bind_enabled = new_value; mutex_enter(&cpu_lock); if (new_value == 0) { for (i = 0; i < sqset_global_size; i++) ip_squeue_set_unbind(sqset_global_list[i]); } else { for (i = 0; i < sqset_global_size; i++) ip_squeue_set_bind(sqset_global_list[i]); } mutex_exit(&cpu_lock); return (0); } /* * Set squeue profiling. * 0 means "disable" * 1 means "enable" * 2 means "enable and reset" */ /* ARGSUSED */ int ip_squeue_profile_set(queue_t *q, mblk_t *mp, char *value, caddr_t cp, cred_t *cr) { int *profile_enabled = (int *)cp; long new_value; squeue_set_t *sqs; if (ddi_strtol(value, NULL, 10, &new_value) != 0) return (EINVAL); if (new_value == 0) squeue_profile_stop(); else if (new_value == 1) squeue_profile_start(); else if (new_value == 2) { int i, j; squeue_profile_stop(); mutex_enter(&cpu_lock); for (i = 0; i < sqset_global_size; i++) { sqs = sqset_global_list[i]; for (j = 0; j < sqs->sqs_size; j++) { squeue_profile_reset(sqs->sqs_list[j]); } } mutex_exit(&cpu_lock); new_value = 1; squeue_profile_start(); } *profile_enabled = new_value; return (0); } /* * Reconfiguration callback */ /* ARGSUSED */ static int ip_squeue_cpu_setup(cpu_setup_t what, int id, void *arg) { cpu_t *cp = cpu[id]; ASSERT(MUTEX_HELD(&cpu_lock)); switch (what) { case CPU_CONFIG: /* * A new CPU is added. Create an squeue for it but do not bind * it yet. */ if (cp->cpu_squeue_set == NULL) cp->cpu_squeue_set = ip_squeue_set_create(cp, B_TRUE); break; case CPU_ON: case CPU_INIT: case CPU_CPUPART_IN: if (cp->cpu_squeue_set == NULL) { cp->cpu_squeue_set = ip_squeue_set_create(cp, B_TRUE); } if (ip_squeue_bind) ip_squeue_set_bind(cp->cpu_squeue_set); break; case CPU_UNCONFIG: case CPU_OFF: case CPU_CPUPART_OUT: ASSERT((cp->cpu_squeue_set != NULL) || (cp->cpu_flags & CPU_OFFLINE)); if (cp->cpu_squeue_set != NULL) { ip_squeue_set_unbind(cp->cpu_squeue_set); } break; default: break; } return (0); } /* ARGSUSED */ static void ip_squeue_set_bind(squeue_set_t *sqs) { int i; squeue_t *sqp; if (!ip_squeue_bind) return; mutex_enter(&sqs->sqs_lock); for (i = 0; i < sqs->sqs_size; i++) { sqp = sqs->sqs_list[i]; if (sqp->sq_state & SQS_BOUND) continue; squeue_bind(sqp, -1); } mutex_exit(&sqs->sqs_lock); } static void ip_squeue_set_unbind(squeue_set_t *sqs) { int i; squeue_t *sqp; mutex_enter(&sqs->sqs_lock); for (i = 0; i < sqs->sqs_size; i++) { sqp = sqs->sqs_list[i]; /* * CPU is going offline. Remove the thread affinity * for any soft ring threads the squeue is managing. */ if (sqp->sq_state & SQS_ILL_BOUND) { ill_rx_ring_t *ring = sqp->sq_rx_ring; ill_t *ill = ring->rr_ill; if (ill->ill_capabilities & ILL_CAPAB_SOFT_RING) { ASSERT(ring->rr_handle != NULL); ill->ill_dls_capab->ill_dls_unbind( ring->rr_handle); } } if (!(sqp->sq_state & SQS_BOUND)) continue; squeue_unbind(sqp); } mutex_exit(&sqs->sqs_lock); }