/* * 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 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* Global locks which protect the interrupt distribution lists */ static kmutex_t intr_dist_lock; static kmutex_t intr_dist_cpu_lock; /* Head of the interrupt distribution lists */ static struct intr_dist *intr_dist_head = NULL; static struct intr_dist *intr_dist_whead = NULL; static uint64_t siron_inum[DDI_IPL_10]; /* software interrupt numbers */ uint64_t *siron_cpu_inum = NULL; uint64_t siron_poke_cpu_inum; static int siron_cpu_setup(cpu_setup_t, int, void *); extern uint_t softlevel1(); static uint64_t siron1_inum; /* backward compatibility */ uint64_t poke_cpu_inum; uint_t poke_cpu_intr(caddr_t arg1, caddr_t arg2); uint_t siron_poke_cpu_intr(caddr_t arg1, caddr_t arg2); /* * Note:- * siron_pending was originally created to prevent a resource over consumption * bug in setsoftint(exhaustion of interrupt pool free list). * It's original intention is obsolete with the use of iv_pending in * setsoftint. However, siron_pending stayed around, acting as a second * gatekeeper preventing soft interrupts from being queued. In this capacity, * it can lead to hangs on MP systems, where due to global visibility issues * it can end up set while iv_pending is reset, preventing soft interrupts from * ever being processed. In addition to its gatekeeper role, init_intr also * uses it to flag the situation where siron() was called before siron_inum has * been defined. * * siron() does not need an extra gatekeeper; any cpu that wishes should be * allowed to queue a soft interrupt. It is softint()'s job to ensure * correct handling of the queues. Therefore, siron_pending has been * stripped of its gatekeeper task, retaining only its intr_init job, where * it indicates that there is a pending need to call siron(). */ static int siron_pending[DDI_IPL_10]; /* software interrupt pending flags */ static int siron1_pending; /* backward compatibility */ int intr_policy = INTR_WEIGHTED_DIST; /* interrupt distribution policy */ int intr_dist_debug = 0; int32_t intr_dist_weight_max = 1; int32_t intr_dist_weight_maxmax = 1000; int intr_dist_weight_maxfactor = 2; #define INTR_DEBUG(args) if (intr_dist_debug) cmn_err args /* * intr_init() - Interrupt initialization * Initialize the system's interrupt vector table. */ void intr_init(cpu_t *cp) { int i; extern uint_t softlevel1(); init_ivintr(); REGISTER_BBUS_INTR(); /* * Register these software interrupts for ddi timer. * Software interrupts up to the level 10 are supported. */ for (i = DDI_IPL_1; i <= DDI_IPL_10; i++) { siron_inum[i-1] = add_softintr(i, (softintrfunc)timer_softintr, (caddr_t)(uintptr_t)(i), SOFTINT_ST); } siron1_inum = add_softintr(PIL_1, softlevel1, 0, SOFTINT_ST); poke_cpu_inum = add_softintr(PIL_13, poke_cpu_intr, 0, SOFTINT_MT); siron_poke_cpu_inum = add_softintr(PIL_13, siron_poke_cpu_intr, 0, SOFTINT_MT); cp->cpu_m.poke_cpu_outstanding = B_FALSE; mutex_init(&intr_dist_lock, NULL, MUTEX_DEFAULT, NULL); mutex_init(&intr_dist_cpu_lock, NULL, MUTEX_DEFAULT, NULL); /* * A soft interrupt may have been requested prior to the initialization * of soft interrupts. Soft interrupts can't be dispatched until after * init_intr(), so we have to wait until now before we can dispatch the * pending soft interrupt (if any). */ for (i = DDI_IPL_1; i <= DDI_IPL_10; i++) { if (siron_pending[i-1]) { siron_pending[i-1] = 0; sir_on(i); } } if (siron1_pending) { siron1_pending = 0; siron(); } } /* * poke_cpu_intr - fall through when poke_cpu calls */ /* ARGSUSED */ uint_t poke_cpu_intr(caddr_t arg1, caddr_t arg2) { CPU->cpu_m.poke_cpu_outstanding = B_FALSE; membar_stld_stst(); return (1); } /* * Trigger software interrupts dedicated to ddi timer. */ void sir_on(int level) { ASSERT(level >= DDI_IPL_1 && level <= DDI_IPL_10); if (siron_inum[level-1]) setsoftint(siron_inum[level-1]); else siron_pending[level-1] = 1; } /* * kmdb uses siron (and thus setsoftint) while the world is stopped in order to * inform its driver component that there's work to be done. We need to keep * DTrace from instrumenting kmdb's siron and setsoftint. We duplicate siron, * giving kmdb's version a kdi_ prefix to keep DTrace at bay. The * implementation of setsoftint is complicated enough that we don't want to * duplicate it, but at the same time we don't want to preclude tracing either. * The meat of setsoftint() therefore goes into kdi_setsoftint, with * setsoftint() implemented as a wrapper. This allows tracing, while still * providing a way for kmdb to sneak in unmolested. */ void kdi_siron(void) { if (siron1_inum != 0) kdi_setsoftint(siron1_inum); else siron1_pending = 1; } void setsoftint(uint64_t inum) { kdi_setsoftint(inum); } /* * Generates softlevel1 interrupt on current CPU if it * is not pending already. */ void siron(void) { uint64_t inum; if (siron1_inum != 0) { /* * Once siron_cpu_inum has been allocated, we can * use per-CPU siron inum. */ if (siron_cpu_inum && siron_cpu_inum[CPU->cpu_id] != 0) inum = siron_cpu_inum[CPU->cpu_id]; else inum = siron1_inum; setsoftint(inum); } else siron1_pending = 1; } static void siron_init(void) { /* * We just allocate memory for per-cpu siron right now. Rest of * the work is done when CPU is configured. */ siron_cpu_inum = kmem_zalloc(sizeof (uint64_t) * NCPU, KM_SLEEP); } /* * This routine creates per-CPU siron inum for CPUs which are * configured during boot. */ void siron_mp_init() { cpu_t *c; /* * Get the memory for per-CPU siron inums */ siron_init(); mutex_enter(&cpu_lock); c = cpu_list; do { (void) siron_cpu_setup(CPU_CONFIG, c->cpu_id, NULL); } while ((c = c->cpu_next) != cpu_list); register_cpu_setup_func(siron_cpu_setup, NULL); mutex_exit(&cpu_lock); } /* * siron_poke_cpu_intr - cross-call handler. */ /* ARGSUSED */ uint_t siron_poke_cpu_intr(caddr_t arg1, caddr_t arg2) { /* generate level1 softint */ siron(); return (1); } /* * This routine generates a cross-call on target CPU(s). */ void siron_poke_cpu(cpuset_t poke) { int cpuid = CPU->cpu_id; if (CPU_IN_SET(poke, cpuid)) { siron(); CPUSET_DEL(poke, cpuid); if (CPUSET_ISNULL(poke)) return; } xt_some(poke, setsoftint_tl1, siron_poke_cpu_inum, 0); } /* * This callback function allows us to create per-CPU siron inum. */ /* ARGSUSED */ static int siron_cpu_setup(cpu_setup_t what, int id, void *arg) { cpu_t *cp = cpu[id]; ASSERT(MUTEX_HELD(&cpu_lock)); ASSERT(cp != NULL); switch (what) { case CPU_CONFIG: siron_cpu_inum[cp->cpu_id] = add_softintr(PIL_1, (softintrfunc)softlevel1, 0, SOFTINT_ST); break; case CPU_UNCONFIG: (void) rem_softintr(siron_cpu_inum[cp->cpu_id]); siron_cpu_inum[cp->cpu_id] = 0; break; default: break; } return (0); } /* * no_ivintr() * called by setvecint_tl1() through sys_trap() * vector interrupt received but not valid or not * registered in intr_vec_table * considered as a spurious mondo interrupt */ /* ARGSUSED */ void no_ivintr(struct regs *rp, int inum, int pil) { cmn_err(CE_WARN, "invalid vector intr: number 0x%x, pil 0x%x", inum, pil); #ifdef DEBUG_VEC_INTR prom_enter_mon(); #endif /* DEBUG_VEC_INTR */ } void intr_dequeue_req(uint_t pil, uint64_t inum) { intr_vec_t *iv, *next, *prev; struct machcpu *mcpu; uint32_t clr; processorid_t cpu_id; extern uint_t getpstate(void); ASSERT((getpstate() & PSTATE_IE) == 0); mcpu = &CPU->cpu_m; cpu_id = CPU->cpu_id; iv = (intr_vec_t *)inum; prev = NULL; next = mcpu->intr_head[pil]; /* Find a matching entry in the list */ while (next != NULL) { if (next == iv) break; prev = next; next = IV_GET_PIL_NEXT(next, cpu_id); } if (next != NULL) { intr_vec_t *next_iv = IV_GET_PIL_NEXT(next, cpu_id); /* Remove entry from list */ if (prev != NULL) IV_SET_PIL_NEXT(prev, cpu_id, next_iv); /* non-head */ else mcpu->intr_head[pil] = next_iv; /* head */ if (next_iv == NULL) mcpu->intr_tail[pil] = prev; /* tail */ } /* Clear pending interrupts at this level if the list is empty */ if (mcpu->intr_head[pil] == NULL) { clr = 1 << pil; if (pil == PIL_14) clr |= (TICK_INT_MASK | STICK_INT_MASK); wr_clr_softint(clr); } } /* * Send a directed interrupt of specified interrupt number id to a cpu. */ void send_dirint( int cpuix, /* cpu to be interrupted */ int intr_id) /* interrupt number id */ { xt_one(cpuix, setsoftint_tl1, intr_id, 0); } /* * Take the specified CPU out of participation in interrupts. * Called by p_online(2) when a processor is being taken off-line. * This allows interrupt threads being handled on the processor to * complete before the processor is idled. */ int cpu_disable_intr(struct cpu *cp) { ASSERT(MUTEX_HELD(&cpu_lock)); /* * Turn off the CPU_ENABLE flag before calling the redistribution * function, since it checks for this in the cpu flags. */ cp->cpu_flags &= ~CPU_ENABLE; intr_redist_all_cpus(); return (0); } /* * Allow the specified CPU to participate in interrupts. * Called by p_online(2) if a processor could not be taken off-line * because of bound threads, in order to resume processing interrupts. * Also called after starting a processor. */ void cpu_enable_intr(struct cpu *cp) { ASSERT(MUTEX_HELD(&cpu_lock)); cp->cpu_flags |= CPU_ENABLE; intr_redist_all_cpus(); } /* * Add function to callback list for intr_redist_all_cpus. We keep two lists, * one for weighted callbacks and one for normal callbacks. Weighted callbacks * are issued to redirect interrupts of a specified weight, from heavy to * light. This allows all the interrupts of a given weight to be redistributed * for all weighted nexus drivers prior to those of less weight. */ static void intr_dist_add_list(struct intr_dist **phead, void (*func)(void *), void *arg) { struct intr_dist *new = kmem_alloc(sizeof (*new), KM_SLEEP); struct intr_dist *iptr; struct intr_dist **pptr; ASSERT(func); new->func = func; new->arg = arg; new->next = NULL; /* Add to tail so that redistribution occurs in original order. */ mutex_enter(&intr_dist_lock); for (iptr = *phead, pptr = phead; iptr != NULL; pptr = &iptr->next, iptr = iptr->next) { /* check for problems as we locate the tail */ if ((iptr->func == func) && (iptr->arg == arg)) { cmn_err(CE_PANIC, "intr_dist_add_list(): duplicate"); /*NOTREACHED*/ } } *pptr = new; mutex_exit(&intr_dist_lock); } void intr_dist_add(void (*func)(void *), void *arg) { intr_dist_add_list(&intr_dist_head, (void (*)(void *))func, arg); } void intr_dist_add_weighted(void (*func)(void *, int32_t, int32_t), void *arg) { intr_dist_add_list(&intr_dist_whead, (void (*)(void *))func, arg); } /* * Search for the interrupt distribution structure with the specified * mondo vec reg in the interrupt distribution list. If a match is found, * then delete the entry from the list. The caller is responsible for * modifying the mondo vector registers. */ static void intr_dist_rem_list(struct intr_dist **headp, void (*func)(void *), void *arg) { struct intr_dist *iptr; struct intr_dist **vect; mutex_enter(&intr_dist_lock); for (iptr = *headp, vect = headp; iptr != NULL; vect = &iptr->next, iptr = iptr->next) { if ((iptr->func == func) && (iptr->arg == arg)) { *vect = iptr->next; kmem_free(iptr, sizeof (struct intr_dist)); mutex_exit(&intr_dist_lock); return; } } if (!panicstr) cmn_err(CE_PANIC, "intr_dist_rem_list: not found"); mutex_exit(&intr_dist_lock); } void intr_dist_rem(void (*func)(void *), void *arg) { intr_dist_rem_list(&intr_dist_head, (void (*)(void *))func, arg); } void intr_dist_rem_weighted(void (*func)(void *, int32_t, int32_t), void *arg) { intr_dist_rem_list(&intr_dist_whead, (void (*)(void *))func, arg); } /* * Initiate interrupt redistribution. Redistribution improves the isolation * associated with interrupt weights by ordering operations from heavy weight * to light weight. When a CPUs orientation changes relative to interrupts, * there is *always* a redistribution to accommodate this change (call to * intr_redist_all_cpus()). As devices (not CPUs) attach/detach it is possible * that a redistribution could improve the quality of an initialization. For * example, if you are not using a NIC it may not be attached with s10 (devfs). * If you then configure the NIC (ifconfig), this may cause the NIC to attach * and plumb interrupts. The CPU assignment for the NIC's interrupts is * occurring late, so optimal "isolation" relative to weight is not occurring. * The same applies to detach, although in this case doing the redistribution * might improve "spread" for medium weight devices since the "isolation" of * a higher weight device may no longer be present. * * NB: We should provide a utility to trigger redistribution (ala "intradm -r"). * * NB: There is risk associated with automatically triggering execution of the * redistribution code at arbitrary times. The risk comes from the fact that * there is a lot of low-level hardware interaction associated with a * redistribution. At some point we may want this code to perform automatic * redistribution (redistribution thread; trigger timeout when add/remove * weight delta is large enough, and call cv_signal from timeout - causing * thead to call i_ddi_intr_redist_all_cpus()) but this is considered too * risky at this time. */ void i_ddi_intr_redist_all_cpus() { mutex_enter(&cpu_lock); INTR_DEBUG((CE_CONT, "intr_dist: i_ddi_intr_redist_all_cpus\n")); intr_redist_all_cpus(); mutex_exit(&cpu_lock); } /* * Redistribute all interrupts * * This function redistributes all interrupting devices, running the * parent callback functions for each node. */ void intr_redist_all_cpus(void) { struct cpu *cp; struct intr_dist *iptr; int32_t weight, max_weight; ASSERT(MUTEX_HELD(&cpu_lock)); mutex_enter(&intr_dist_lock); /* * zero cpu_intr_weight on all cpus - it is safe to traverse * cpu_list since we hold cpu_lock. */ cp = cpu_list; do { cp->cpu_intr_weight = 0; } while ((cp = cp->cpu_next) != cpu_list); /* * Assume that this redistribution may encounter a device weight * via driver.conf tuning of "ddi-intr-weight" that is at most * intr_dist_weight_maxfactor times larger. */ max_weight = intr_dist_weight_max * intr_dist_weight_maxfactor; if (max_weight > intr_dist_weight_maxmax) max_weight = intr_dist_weight_maxmax; intr_dist_weight_max = 1; INTR_DEBUG((CE_CONT, "intr_dist: " "intr_redist_all_cpus: %d-0\n", max_weight)); /* * Redistribute weighted, from heavy to light. The callback that * specifies a weight equal to weight_max should redirect all * interrupts of weight weight_max or greater [weight_max, inf.). * Interrupts of lesser weight should be processed on the call with * the matching weight. This allows all the heaver weight interrupts * on all weighted busses (multiple pci busses) to be redirected prior * to any lesser weight interrupts. */ for (weight = max_weight; weight >= 0; weight--) for (iptr = intr_dist_whead; iptr != NULL; iptr = iptr->next) ((void (*)(void *, int32_t, int32_t))iptr->func) (iptr->arg, max_weight, weight); /* redistribute normal (non-weighted) interrupts */ for (iptr = intr_dist_head; iptr != NULL; iptr = iptr->next) ((void (*)(void *))iptr->func)(iptr->arg); mutex_exit(&intr_dist_lock); } void intr_redist_all_cpus_shutdown(void) { intr_policy = INTR_CURRENT_CPU; intr_redist_all_cpus(); } /* * Determine what CPU to target, based on interrupt policy. * * INTR_FLAT_DIST: hold a current CPU pointer in a static variable and * advance through interrupt enabled cpus (round-robin). * * INTR_WEIGHTED_DIST: search for an enabled CPU with the lowest * cpu_intr_weight, round robin when all equal. * * Weighted interrupt distribution provides two things: "spread" of weight * (associated with algorithm itself) and "isolation" (associated with a * particular device weight). A redistribution is what provides optimal * "isolation" of heavy weight interrupts, optimal "spread" of weight * (relative to what came before) is always occurring. * * An interrupt weight is a subjective number that represents the * percentage of a CPU required to service a device's interrupts: the * default weight is 0% (however the algorithm still maintains * round-robin), a network interface controller (NIC) may have a large * weight (35%). Interrupt weight only has meaning relative to the * interrupt weight of other devices: a CPU can be weighted more than * 100%, and a single device might consume more than 100% of a CPU. * * A coarse interrupt weight can be defined by the parent nexus driver * based on bus specific information, like pci class codes. A nexus * driver that supports device interrupt weighting for its children * should call intr_dist_cpuid_add/rem_device_weight(), which adds * and removes the weight of a device from the CPU that an interrupt * is directed at. The quality of initialization improves when the * device interrupt weights more accuracy reflect actual run-time weights, * and as the assignments are ordered from is heavy to light. * * The implementation also supports interrupt weight being specified in * driver.conf files via the property "ddi-intr-weight", which takes * precedence over the nexus supplied weight. This support is added to * permit possible tweaking in the product in response to customer * problems. This is not a formal or committed interface. * * While a weighted approach chooses the CPU providing the best spread * given past weights, less than optimal isolation can result in cases * where heavy weight devices show up last. The nexus driver's interrupt * redistribution logic should use intr_dist_add/rem_weighted so that * interrupts can be redistributed heavy first for optimal isolation. */ uint32_t intr_dist_cpuid(void) { static struct cpu *curr_cpu; struct cpu *start_cpu; struct cpu *new_cpu; struct cpu *cp; int cpuid = -1; /* Establish exclusion for curr_cpu and cpu_intr_weight manipulation */ mutex_enter(&intr_dist_cpu_lock); switch (intr_policy) { case INTR_CURRENT_CPU: cpuid = CPU->cpu_id; break; case INTR_BOOT_CPU: panic("INTR_BOOT_CPU no longer supported."); /*NOTREACHED*/ case INTR_FLAT_DIST: case INTR_WEIGHTED_DIST: default: /* * Ensure that curr_cpu is valid - cpu_next will be NULL if * the cpu has been deleted (cpu structs are never freed). */ if (curr_cpu == NULL || curr_cpu->cpu_next == NULL) curr_cpu = CPU; /* * Advance to online CPU after curr_cpu (round-robin). For * INTR_WEIGHTED_DIST we choose the cpu with the lightest * weight. For a nexus that does not support weight the * default weight of zero is used. We degrade to round-robin * behavior among equal weightes. The default weight is zero * and round-robin behavior continues. * * Disable preemption while traversing cpu_next_onln to * ensure the list does not change. This works because * modifiers of this list and other lists in a struct cpu * call pause_cpus() before making changes. */ kpreempt_disable(); cp = start_cpu = curr_cpu->cpu_next_onln; new_cpu = NULL; do { /* Skip CPUs with interrupts disabled */ if ((cp->cpu_flags & CPU_ENABLE) == 0) continue; if (intr_policy == INTR_FLAT_DIST) { /* select CPU */ new_cpu = cp; break; } else if ((new_cpu == NULL) || (cp->cpu_intr_weight < new_cpu->cpu_intr_weight)) { /* Choose if lighter weight */ new_cpu = cp; } } while ((cp = cp->cpu_next_onln) != start_cpu); ASSERT(new_cpu); cpuid = new_cpu->cpu_id; INTR_DEBUG((CE_CONT, "intr_dist: cpu %2d weight %3d: " "targeted\n", cpuid, new_cpu->cpu_intr_weight)); /* update static pointer for next round-robin */ curr_cpu = new_cpu; kpreempt_enable(); break; } mutex_exit(&intr_dist_cpu_lock); return (cpuid); } /* * Add or remove the the weight of a device from a CPUs interrupt weight. * * We expect nexus drivers to call intr_dist_cpuid_add/rem_device_weight for * their children to improve the overall quality of interrupt initialization. * * If a nexues shares the CPU returned by a single intr_dist_cpuid() call * among multiple devices (sharing ino) then the nexus should call * intr_dist_cpuid_add/rem_device_weight for each device separately. Devices * that share must specify the same cpuid. * * If a nexus driver is unable to determine the cpu at remove_intr time * for some of its interrupts, then it should not call add_device_weight - * intr_dist_cpuid will still provide round-robin. * * An established device weight (from dev_info node) takes precedence over * the weight passed in. If a device weight is not already established * then the passed in nexus weight is established. */ void intr_dist_cpuid_add_device_weight(uint32_t cpuid, dev_info_t *dip, int32_t nweight) { int32_t eweight; /* * For non-weighted policy everything has weight of zero (and we get * round-robin distribution from intr_dist_cpuid). * NB: intr_policy is limited to this file. A weighted nexus driver is * calls this rouitne even if intr_policy has been patched to * INTR_FLAG_DIST. */ ASSERT(dip); if (intr_policy != INTR_WEIGHTED_DIST) return; eweight = i_ddi_get_intr_weight(dip); INTR_DEBUG((CE_CONT, "intr_dist: cpu %2d weight %3d: +%2d/%2d for " "%s#%d/%s#%d\n", cpuid, cpu[cpuid]->cpu_intr_weight, nweight, eweight, ddi_driver_name(ddi_get_parent(dip)), ddi_get_instance(ddi_get_parent(dip)), ddi_driver_name(dip), ddi_get_instance(dip))); /* if no establish weight, establish nexus weight */ if (eweight < 0) { if (nweight > 0) (void) i_ddi_set_intr_weight(dip, nweight); else nweight = 0; } else nweight = eweight; /* use established weight */ /* Establish exclusion for cpu_intr_weight manipulation */ mutex_enter(&intr_dist_cpu_lock); cpu[cpuid]->cpu_intr_weight += nweight; /* update intr_dist_weight_max */ if (nweight > intr_dist_weight_max) intr_dist_weight_max = nweight; mutex_exit(&intr_dist_cpu_lock); } void intr_dist_cpuid_rem_device_weight(uint32_t cpuid, dev_info_t *dip) { struct cpu *cp; int32_t weight; ASSERT(dip); if (intr_policy != INTR_WEIGHTED_DIST) return; /* remove weight of device from cpu */ weight = i_ddi_get_intr_weight(dip); if (weight < 0) weight = 0; INTR_DEBUG((CE_CONT, "intr_dist: cpu %2d weight %3d: -%2d for " "%s#%d/%s#%d\n", cpuid, cpu[cpuid]->cpu_intr_weight, weight, ddi_driver_name(ddi_get_parent(dip)), ddi_get_instance(ddi_get_parent(dip)), ddi_driver_name(dip), ddi_get_instance(dip))); /* Establish exclusion for cpu_intr_weight manipulation */ mutex_enter(&intr_dist_cpu_lock); cp = cpu[cpuid]; cp->cpu_intr_weight -= weight; if (cp->cpu_intr_weight < 0) cp->cpu_intr_weight = 0; /* sanity */ mutex_exit(&intr_dist_cpu_lock); } ulong_t create_softint(uint_t pil, uint_t (*func)(caddr_t, caddr_t), caddr_t arg1) { uint64_t inum; inum = add_softintr(pil, func, arg1, SOFTINT_ST); return ((ulong_t)inum); } void invoke_softint(processorid_t cpuid, ulong_t hdl) { uint64_t inum = hdl; if (cpuid == CPU->cpu_id) setsoftint(inum); else xt_one(cpuid, setsoftint_tl1, inum, 0); } void remove_softint(ulong_t hdl) { uint64_t inum = hdl; (void) rem_softintr(inum); } void sync_softint(cpuset_t set) { xt_sync(set); }