/****************************************************************************** * xen_intr.c * * Xen event and interrupt services for x86 HVM guests. * * Copyright (c) 2002-2005, K A Fraser * Copyright (c) 2005, Intel Corporation * Copyright (c) 2012, Spectra Logic Corporation * Copyright © 2021-2023, Elliott Mitchell * * This file may be distributed separately from the Linux kernel, or * incorporated into other software packages, subject to the following license: * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this source file (the "Software"), to deal in the Software without * restriction, including without limitation the rights to use, copy, modify, * merge, publish, distribute, sublicense, and/or sell copies of the Software, * and to permit persons to whom the Software is furnished to do so, subject to * the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS * IN THE SOFTWARE. */ #include #include "opt_ddb.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef DDB #include #endif /** * Per-cpu event channel processing state. */ struct xen_intr_pcpu_data { /** * The last event channel bitmap section (level one bit) processed. * This is used to ensure we scan all ports before * servicing an already servied port again. */ u_int last_processed_l1i; /** * The last event channel processed within the event channel * bitmap being scanned. */ u_int last_processed_l2i; /** * A bitmap of ports that can be serviced from this CPU. * A set bit means interrupt handling is enabled. */ u_long evtchn_enabled[sizeof(u_long) * 8]; }; /* * Start the scan at port 0 by initializing the last scanned * location as the highest numbered event channel port. */ DPCPU_DEFINE_STATIC(struct xen_intr_pcpu_data, xen_intr_pcpu) = { .last_processed_l1i = LONG_BIT - 1, .last_processed_l2i = LONG_BIT - 1 }; DPCPU_DECLARE(struct vcpu_info *, vcpu_info); #define INVALID_EVTCHN (~(evtchn_port_t)0) /* Invalid event channel */ #define is_valid_evtchn(x) ((uintmax_t)(x) < NR_EVENT_CHANNELS) /* * Lock for interrupt core data. * * Modifying xen_intr_port_to_isrc[], or isrc->xi_port (implies the former) * requires this lock be held. Any time this lock is not held, the condition * `!xen_intr_port_to_isrc[i] || (xen_intr_port_to_isrc[i]->ix_port == i)` * MUST be true for all values of i which are valid indicies of the array. * * Acquire/release operations for isrc->xi_refcount require this lock be held. */ static struct mtx xen_intr_isrc_lock; static struct xenisrc *xen_intr_port_to_isrc[NR_EVENT_CHANNELS]; /*------------------------- Private Functions --------------------------------*/ /** * Retrieve a handle for a Xen interrupt source. * * \param isrc A valid Xen interrupt source structure. * * \returns A handle suitable for use with xen_intr_isrc_from_handle() * to retrieve the original Xen interrupt source structure. */ static inline xen_intr_handle_t xen_intr_handle_from_isrc(struct xenisrc *isrc) { return (isrc); } /** * Lookup a Xen interrupt source object given an interrupt binding handle. * * \param handle A handle initialized by a previous call to * xen_intr_bind_isrc(). * * \returns A pointer to the Xen interrupt source object associated * with the given interrupt handle. NULL if no association * currently exists. */ static inline struct xenisrc * xen_intr_isrc_from_handle(xen_intr_handle_t handle) { return ((struct xenisrc *)handle); } /** * Disable signal delivery for an event channel port on the * specified CPU. * * \param port The event channel port to mask. * * This API is used to manage the port<=>CPU binding of event * channel handlers. * * \note This operation does not preclude reception of an event * for this event channel on another CPU. To mask the * event channel globally, use evtchn_mask(). */ static inline void evtchn_cpu_mask_port(u_int cpu, evtchn_port_t port) { struct xen_intr_pcpu_data *pcpu; pcpu = DPCPU_ID_PTR(cpu, xen_intr_pcpu); xen_clear_bit(port, pcpu->evtchn_enabled); } /** * Enable signal delivery for an event channel port on the * specified CPU. * * \param port The event channel port to unmask. * * This API is used to manage the port<=>CPU binding of event * channel handlers. * * \note This operation does not guarantee that event delivery * is enabled for this event channel port. The port must * also be globally enabled. See evtchn_unmask(). */ static inline void evtchn_cpu_unmask_port(u_int cpu, evtchn_port_t port) { struct xen_intr_pcpu_data *pcpu; pcpu = DPCPU_ID_PTR(cpu, xen_intr_pcpu); xen_set_bit(port, pcpu->evtchn_enabled); } /** * Attempt to free an active Xen interrupt source object. * * \param isrc The interrupt source object to release. * * \returns EBUSY if the source is still in use, otherwise 0. */ static int xen_intr_release_isrc(struct xenisrc *isrc) { mtx_lock(&xen_intr_isrc_lock); if (is_valid_evtchn(isrc->xi_port)) { evtchn_mask_port(isrc->xi_port); evtchn_clear_port(isrc->xi_port); /* Rebind port to CPU 0. */ evtchn_cpu_mask_port(isrc->xi_cpu, isrc->xi_port); evtchn_cpu_unmask_port(0, isrc->xi_port); if (isrc->xi_close != 0) { struct evtchn_close close = { .port = isrc->xi_port }; if (HYPERVISOR_event_channel_op(EVTCHNOP_close, &close)) panic("EVTCHNOP_close failed"); } xen_intr_port_to_isrc[isrc->xi_port] = NULL; } /* not reachable from xen_intr_port_to_isrc[], unlock */ mtx_unlock(&xen_intr_isrc_lock); xen_arch_intr_release(isrc); return (0); } /** * Associate an interrupt handler with an already allocated local Xen * event channel port. * * \param isrcp The returned Xen interrupt object associated with * the specified local port. * \param local_port The event channel to bind. * \param type The event channel type of local_port. * \param intr_owner The device making this bind request. * \param filter An interrupt filter handler. Specify NULL * to always dispatch to the ithread handler. * \param handler An interrupt ithread handler. Optional (can * specify NULL) if all necessary event actions * are performed by filter. * \param arg Argument to present to both filter and handler. * \param irqflags Interrupt handler flags. See sys/bus.h. * \param handlep Pointer to an opaque handle used to manage this * registration. * * \returns 0 on success, otherwise an errno. */ static int xen_intr_bind_isrc(struct xenisrc **isrcp, evtchn_port_t local_port, enum evtchn_type type, const char *intr_owner, driver_filter_t filter, driver_intr_t handler, void *arg, enum intr_type flags, xen_intr_handle_t *const port_handlep) { struct xenisrc *isrc; int error; *isrcp = NULL; if (port_handlep == NULL) { printf("%s: %s: Bad event handle\n", intr_owner, __func__); return (EINVAL); } *port_handlep = NULL; isrc = xen_arch_intr_alloc(); if (isrc == NULL) return (ENOSPC); isrc->xi_cookie = NULL; isrc->xi_type = type; isrc->xi_port = local_port; isrc->xi_close = false; isrc->xi_cpu = 0; refcount_init(&isrc->xi_refcount, 1); mtx_lock(&xen_intr_isrc_lock); xen_intr_port_to_isrc[isrc->xi_port] = isrc; mtx_unlock(&xen_intr_isrc_lock); #ifdef SMP if (type == EVTCHN_TYPE_PORT) { /* * By default all interrupts are assigned to vCPU#0 * unless specified otherwise, so shuffle them to balance * the interrupt load. */ xen_intr_assign_cpu(isrc, xen_arch_intr_next_cpu(isrc)); } #endif /* * If a filter or handler function is provided, add it to the event. * Otherwise the event channel is left masked and without a handler, * the caller is in charge of setting that up. */ if (filter != NULL || handler != NULL) { error = xen_intr_add_handler(intr_owner, filter, handler, arg, flags, xen_intr_handle_from_isrc(isrc)); if (error != 0) { xen_intr_release_isrc(isrc); return (error); } } *isrcp = isrc; /* Assign the opaque handler */ *port_handlep = xen_intr_handle_from_isrc(isrc); return (0); } /** * Determine the event channel ports at the given section of the * event port bitmap which have pending events for the given cpu. * * \param pcpu The Xen interrupt pcpu data for the cpu being queried. * \param sh The Xen shared info area. * \param idx The index of the section of the event channel bitmap to * inspect. * * \returns A u_long with bits set for every event channel with pending * events. */ static inline u_long xen_intr_active_ports(const struct xen_intr_pcpu_data *const pcpu, const u_int idx) { volatile const shared_info_t *const sh = HYPERVISOR_shared_info; CTASSERT(sizeof(sh->evtchn_mask[0]) == sizeof(sh->evtchn_pending[0])); CTASSERT(sizeof(sh->evtchn_mask[0]) == sizeof(pcpu->evtchn_enabled[0])); CTASSERT(sizeof(sh->evtchn_mask) == sizeof(sh->evtchn_pending)); CTASSERT(sizeof(sh->evtchn_mask) == sizeof(pcpu->evtchn_enabled)); return (sh->evtchn_pending[idx] & ~sh->evtchn_mask[idx] & pcpu->evtchn_enabled[idx]); } /** * Interrupt handler for processing all Xen event channel events. * * \param trap_frame The trap frame context for the current interrupt. */ int xen_intr_handle_upcall(void *unused __unused) { struct trapframe *trap_frame = curthread->td_intr_frame; u_int l1i, l2i, port, cpu __diagused; u_long masked_l1, masked_l2; struct xenisrc *isrc; vcpu_info_t *v; struct xen_intr_pcpu_data *pc; u_long l1, l2; /* We must remain on the same vCPU during this function */ CRITICAL_ASSERT(curthread); cpu = PCPU_GET(cpuid); pc = DPCPU_PTR(xen_intr_pcpu); v = DPCPU_GET(vcpu_info); if (!xen_has_percpu_evtchn()) { KASSERT((cpu == 0), ("Fired PCI event callback on wrong CPU")); } v->evtchn_upcall_pending = 0; /* No need for a barrier on x86 -- XCHG is a barrier on x86. */ #if !defined(__amd64__) && !defined(__i386__) /* Clear master flag /before/ clearing selector flag. */ wmb(); #endif l1 = atomic_readandclear_long(&v->evtchn_pending_sel); l1i = pc->last_processed_l1i; l2i = pc->last_processed_l2i; while (l1 != 0) { l1i = (l1i + 1) % LONG_BIT; masked_l1 = l1 & ((~0UL) << l1i); if (masked_l1 == 0) { /* * if we masked out all events, wrap around * to the beginning. */ l1i = LONG_BIT - 1; l2i = LONG_BIT - 1; continue; } l1i = ffsl(masked_l1) - 1; do { l2 = xen_intr_active_ports(pc, l1i); l2i = (l2i + 1) % LONG_BIT; masked_l2 = l2 & ((~0UL) << l2i); if (masked_l2 == 0) { /* if we masked out all events, move on */ l2i = LONG_BIT - 1; break; } l2i = ffsl(masked_l2) - 1; /* process port */ port = (l1i * LONG_BIT) + l2i; evtchn_clear_port(port); isrc = xen_intr_port_to_isrc[port]; if (__predict_false(isrc == NULL)) continue; /* Make sure we are firing on the right vCPU */ KASSERT((isrc->xi_cpu == PCPU_GET(cpuid)), ("Received unexpected event on vCPU#%u, event bound to vCPU#%u", PCPU_GET(cpuid), isrc->xi_cpu)); xen_arch_intr_execute_handlers(isrc, trap_frame); /* * If this is the final port processed, * we'll pick up here+1 next time. */ pc->last_processed_l1i = l1i; pc->last_processed_l2i = l2i; } while (l2i != LONG_BIT - 1); l2 = xen_intr_active_ports(pc, l1i); if (l2 == 0) { /* * We handled all ports, so we can clear the * selector bit. */ l1 &= ~(1UL << l1i); } } return (FILTER_HANDLED); } static int xen_intr_init(void *dummy __unused) { shared_info_t *s = HYPERVISOR_shared_info; struct xen_intr_pcpu_data *pcpu; int i; if (!xen_domain()) return (0); _Static_assert(is_valid_evtchn(0), "is_valid_evtchn(0) fails (unused by Xen, but valid by interface"); _Static_assert(is_valid_evtchn(NR_EVENT_CHANNELS - 1), "is_valid_evtchn(max) fails (is a valid channel)"); _Static_assert(!is_valid_evtchn(NR_EVENT_CHANNELS), "is_valid_evtchn(>max) fails (NOT a valid channel)"); _Static_assert(!is_valid_evtchn(~(evtchn_port_t)0), "is_valid_evtchn(maxint) fails (overflow?)"); _Static_assert(!is_valid_evtchn(INVALID_EVTCHN), "is_valid_evtchn(INVALID_EVTCHN) fails (must be invalid!)"); _Static_assert(!is_valid_evtchn(-1), "is_valid_evtchn(-1) fails (negative are invalid)"); mtx_init(&xen_intr_isrc_lock, "xen-irq-lock", NULL, MTX_DEF); /* * Set the per-cpu mask of CPU#0 to enable all, since by default all * event channels are bound to CPU#0. */ CPU_FOREACH(i) { pcpu = DPCPU_ID_PTR(i, xen_intr_pcpu); memset(pcpu->evtchn_enabled, i == 0 ? ~0 : 0, sizeof(pcpu->evtchn_enabled)); } for (i = 0; i < nitems(s->evtchn_mask); i++) atomic_store_rel_long(&s->evtchn_mask[i], ~0); xen_arch_intr_init(); if (bootverbose) printf("Xen interrupt system initialized\n"); return (0); } SYSINIT(xen_intr_init, SI_SUB_INTR, SI_ORDER_SECOND, xen_intr_init, NULL); /*--------------------------- Common PIC Functions ---------------------------*/ static void xen_rebind_ipi(struct xenisrc *isrc) { #ifdef SMP u_int cpu = isrc->xi_cpu; u_int vcpu_id = XEN_CPUID_TO_VCPUID(cpu); int error; struct evtchn_bind_ipi bind_ipi = { .vcpu = vcpu_id }; error = HYPERVISOR_event_channel_op(EVTCHNOP_bind_ipi, &bind_ipi); if (error != 0) panic("unable to rebind xen IPI: %d", error); isrc->xi_port = bind_ipi.port; #else panic("Resume IPI event channel on UP"); #endif } static void xen_rebind_virq(struct xenisrc *isrc) { u_int cpu = isrc->xi_cpu; u_int vcpu_id = XEN_CPUID_TO_VCPUID(cpu); int error; struct evtchn_bind_virq bind_virq = { .virq = isrc->xi_virq, .vcpu = vcpu_id }; error = HYPERVISOR_event_channel_op(EVTCHNOP_bind_virq, &bind_virq); if (error != 0) panic("unable to rebind xen VIRQ#%u: %d", isrc->xi_virq, error); isrc->xi_port = bind_virq.port; } static struct xenisrc * xen_intr_rebind_isrc(struct xenisrc *isrc) { #ifdef SMP u_int cpu = isrc->xi_cpu; int error; #endif struct xenisrc *prev; switch (isrc->xi_type) { case EVTCHN_TYPE_IPI: xen_rebind_ipi(isrc); break; case EVTCHN_TYPE_VIRQ: xen_rebind_virq(isrc); break; default: return (NULL); } prev = xen_intr_port_to_isrc[isrc->xi_port]; xen_intr_port_to_isrc[isrc->xi_port] = isrc; #ifdef SMP isrc->xi_cpu = 0; error = xen_intr_assign_cpu(isrc, cpu); if (error) panic("%s(): unable to rebind Xen channel %u to vCPU%u: %d", __func__, isrc->xi_port, cpu, error); #endif evtchn_unmask_port(isrc->xi_port); return (prev); } /** * Return this PIC to service after being suspended. */ void xen_intr_resume(void) { shared_info_t *s = HYPERVISOR_shared_info; u_int isrc_idx; int i; /* Reset the per-CPU masks */ CPU_FOREACH(i) { struct xen_intr_pcpu_data *pcpu; pcpu = DPCPU_ID_PTR(i, xen_intr_pcpu); memset(pcpu->evtchn_enabled, i == 0 ? ~0 : 0, sizeof(pcpu->evtchn_enabled)); } /* Mask all event channels. */ for (i = 0; i < nitems(s->evtchn_mask); i++) atomic_store_rel_long(&s->evtchn_mask[i], ~0); /* Clear existing port mappings */ for (isrc_idx = 0; isrc_idx < NR_EVENT_CHANNELS; ++isrc_idx) if (xen_intr_port_to_isrc[isrc_idx] != NULL) xen_intr_port_to_isrc[isrc_idx]->xi_port = INVALID_EVTCHN; /* Remap in-use isrcs, using xen_intr_port_to_isrc as listing */ for (isrc_idx = 0; isrc_idx < NR_EVENT_CHANNELS; ++isrc_idx) { struct xenisrc *cur = xen_intr_port_to_isrc[isrc_idx]; /* empty or entry already taken care of */ if (cur == NULL || cur->xi_port == isrc_idx) continue; xen_intr_port_to_isrc[isrc_idx] = NULL; do { KASSERT(!is_valid_evtchn(cur->xi_port), ("%s(): Multiple channels on single intr?", __func__)); cur = xen_intr_rebind_isrc(cur); } while (cur != NULL); } } /** * Disable a Xen interrupt source. * * \param isrc The interrupt source to disable. */ void xen_intr_disable_intr(struct xenisrc *isrc) { evtchn_mask_port(isrc->xi_port); } /** * Configure CPU affinity for interrupt source event delivery. * * \param isrc The interrupt source to configure. * \param to_cpu The id of the CPU for handling future events. * * \returns 0 if successful, otherwise an errno. */ int xen_intr_assign_cpu(struct xenisrc *isrc, u_int to_cpu) { #ifdef SMP struct evtchn_bind_vcpu bind_vcpu; u_int vcpu_id = XEN_CPUID_TO_VCPUID(to_cpu); int error, masked; if (!xen_has_percpu_evtchn()) return (EOPNOTSUPP); mtx_lock(&xen_intr_isrc_lock); if (!is_valid_evtchn(isrc->xi_port)) { mtx_unlock(&xen_intr_isrc_lock); return (EINVAL); } /* * Mask the event channel while binding it to prevent interrupt * delivery with an inconsistent state in isrc->xi_cpu. */ masked = evtchn_test_and_set_mask(isrc->xi_port); if ((isrc->xi_type == EVTCHN_TYPE_VIRQ) || (isrc->xi_type == EVTCHN_TYPE_IPI)) { /* * Virtual IRQs are associated with a cpu by * the Hypervisor at evtchn_bind_virq time, so * all we need to do is update the per-CPU masks. */ evtchn_cpu_mask_port(isrc->xi_cpu, isrc->xi_port); isrc->xi_cpu = to_cpu; evtchn_cpu_unmask_port(isrc->xi_cpu, isrc->xi_port); goto out; } bind_vcpu.port = isrc->xi_port; bind_vcpu.vcpu = vcpu_id; error = HYPERVISOR_event_channel_op(EVTCHNOP_bind_vcpu, &bind_vcpu); if (isrc->xi_cpu != to_cpu) { if (error == 0) { /* Commit to new binding by removing the old one. */ evtchn_cpu_mask_port(isrc->xi_cpu, isrc->xi_port); isrc->xi_cpu = to_cpu; evtchn_cpu_unmask_port(isrc->xi_cpu, isrc->xi_port); } } out: if (masked == 0) evtchn_unmask_port(isrc->xi_port); mtx_unlock(&xen_intr_isrc_lock); return (0); #else return (EOPNOTSUPP); #endif } /*------------------- Virtual Interrupt Source PIC Functions -----------------*/ /* * Mask a level triggered interrupt source. * * \param isrc The interrupt source to mask (if necessary). */ void xen_intr_disable_source(struct xenisrc *isrc) { /* * NB: checking if the event channel is already masked is * needed because the event channel user-space device * masks event channels on its filter as part of its * normal operation, and those shouldn't be automatically * unmasked by the generic interrupt code. The event channel * device will unmask them when needed. */ isrc->xi_masked = !!evtchn_test_and_set_mask(isrc->xi_port); } /* * Unmask a level triggered interrupt source. * * \param isrc The interrupt source to unmask (if necessary). */ void xen_intr_enable_source(struct xenisrc *isrc) { if (isrc->xi_masked == 0) evtchn_unmask_port(isrc->xi_port); } /* * Enable and unmask the interrupt source. * * \param isrc The interrupt source to enable. */ void xen_intr_enable_intr(struct xenisrc *isrc) { evtchn_unmask_port(isrc->xi_port); } /*--------------------------- Public Functions -------------------------------*/ /*------- API comments for these methods can be found in xen/xenintr.h -------*/ int xen_intr_bind_local_port(device_t dev, evtchn_port_t local_port, driver_filter_t filter, driver_intr_t handler, void *arg, enum intr_type flags, xen_intr_handle_t *port_handlep) { struct xenisrc *isrc; int error; error = xen_intr_bind_isrc(&isrc, local_port, EVTCHN_TYPE_PORT, device_get_nameunit(dev), filter, handler, arg, flags, port_handlep); if (error != 0) return (error); /* * The Event Channel API didn't open this port, so it is not * responsible for closing it automatically on unbind. */ isrc->xi_close = 0; return (0); } int xen_intr_alloc_and_bind_local_port(device_t dev, u_int remote_domain, driver_filter_t filter, driver_intr_t handler, void *arg, enum intr_type flags, xen_intr_handle_t *port_handlep) { struct xenisrc *isrc; struct evtchn_alloc_unbound alloc_unbound; int error; alloc_unbound.dom = DOMID_SELF; alloc_unbound.remote_dom = remote_domain; error = HYPERVISOR_event_channel_op(EVTCHNOP_alloc_unbound, &alloc_unbound); if (error != 0) { /* * XXX Trap Hypercall error code Linuxisms in * the HYPERCALL layer. */ return (-error); } error = xen_intr_bind_isrc(&isrc, alloc_unbound.port, EVTCHN_TYPE_PORT, device_get_nameunit(dev), filter, handler, arg, flags, port_handlep); if (error != 0) { evtchn_close_t close = { .port = alloc_unbound.port }; if (HYPERVISOR_event_channel_op(EVTCHNOP_close, &close)) panic("EVTCHNOP_close failed"); return (error); } isrc->xi_close = 1; return (0); } int xen_intr_bind_remote_port(device_t dev, u_int remote_domain, u_int remote_port, driver_filter_t filter, driver_intr_t handler, void *arg, enum intr_type flags, xen_intr_handle_t *port_handlep) { struct xenisrc *isrc; struct evtchn_bind_interdomain bind_interdomain; int error; bind_interdomain.remote_dom = remote_domain; bind_interdomain.remote_port = remote_port; error = HYPERVISOR_event_channel_op(EVTCHNOP_bind_interdomain, &bind_interdomain); if (error != 0) { /* * XXX Trap Hypercall error code Linuxisms in * the HYPERCALL layer. */ return (-error); } error = xen_intr_bind_isrc(&isrc, bind_interdomain.local_port, EVTCHN_TYPE_PORT, device_get_nameunit(dev), filter, handler, arg, flags, port_handlep); if (error) { evtchn_close_t close = { .port = bind_interdomain.local_port }; if (HYPERVISOR_event_channel_op(EVTCHNOP_close, &close)) panic("EVTCHNOP_close failed"); return (error); } /* * The Event Channel API opened this port, so it is * responsible for closing it automatically on unbind. */ isrc->xi_close = 1; return (0); } int xen_intr_bind_virq(device_t dev, u_int virq, u_int cpu, driver_filter_t filter, driver_intr_t handler, void *arg, enum intr_type flags, xen_intr_handle_t *port_handlep) { u_int vcpu_id = XEN_CPUID_TO_VCPUID(cpu); struct xenisrc *isrc; struct evtchn_bind_virq bind_virq = { .virq = virq, .vcpu = vcpu_id }; int error; isrc = NULL; error = HYPERVISOR_event_channel_op(EVTCHNOP_bind_virq, &bind_virq); if (error != 0) { /* * XXX Trap Hypercall error code Linuxisms in * the HYPERCALL layer. */ return (-error); } error = xen_intr_bind_isrc(&isrc, bind_virq.port, EVTCHN_TYPE_VIRQ, device_get_nameunit(dev), filter, handler, arg, flags, port_handlep); #ifdef SMP if (error == 0) error = xen_arch_intr_event_bind(isrc, cpu); #endif if (error != 0) { evtchn_close_t close = { .port = bind_virq.port }; xen_intr_unbind(port_handlep); if (HYPERVISOR_event_channel_op(EVTCHNOP_close, &close)) panic("EVTCHNOP_close failed"); return (error); } #ifdef SMP if (isrc->xi_cpu != cpu) { /* * Too early in the boot process for the generic interrupt * code to perform the binding. Update our event channel * masks manually so events can't fire on the wrong cpu * during AP startup. */ xen_intr_assign_cpu(isrc, cpu); } #endif /* * The Event Channel API opened this port, so it is * responsible for closing it automatically on unbind. */ isrc->xi_close = 1; isrc->xi_virq = virq; return (0); } int xen_intr_alloc_and_bind_ipi(u_int cpu, driver_filter_t filter, enum intr_type flags, xen_intr_handle_t *port_handlep) { #ifdef SMP u_int vcpu_id = XEN_CPUID_TO_VCPUID(cpu); struct xenisrc *isrc; struct evtchn_bind_ipi bind_ipi = { .vcpu = vcpu_id }; /* Same size as the one used by intr_handler->ih_name. */ char name[MAXCOMLEN + 1]; int error; isrc = NULL; error = HYPERVISOR_event_channel_op(EVTCHNOP_bind_ipi, &bind_ipi); if (error != 0) { /* * XXX Trap Hypercall error code Linuxisms in * the HYPERCALL layer. */ return (-error); } snprintf(name, sizeof(name), "cpu%u", cpu); error = xen_intr_bind_isrc(&isrc, bind_ipi.port, EVTCHN_TYPE_IPI, name, filter, NULL, NULL, flags, port_handlep); if (error != 0) { evtchn_close_t close = { .port = bind_ipi.port }; xen_intr_unbind(port_handlep); if (HYPERVISOR_event_channel_op(EVTCHNOP_close, &close)) panic("EVTCHNOP_close failed"); return (error); } if (isrc->xi_cpu != cpu) { /* * Too early in the boot process for the generic interrupt * code to perform the binding. Update our event channel * masks manually so events can't fire on the wrong cpu * during AP startup. */ xen_intr_assign_cpu(isrc, cpu); } /* * The Event Channel API opened this port, so it is * responsible for closing it automatically on unbind. */ isrc->xi_close = 1; return (0); #else return (EOPNOTSUPP); #endif } int xen_intr_describe(xen_intr_handle_t port_handle, const char *fmt, ...) { char descr[MAXCOMLEN + 1]; struct xenisrc *isrc; va_list ap; isrc = xen_intr_isrc_from_handle(port_handle); if (isrc == NULL) return (EINVAL); va_start(ap, fmt); vsnprintf(descr, sizeof(descr), fmt, ap); va_end(ap); return (xen_arch_intr_describe(isrc, isrc->xi_cookie, descr)); } void xen_intr_unbind(xen_intr_handle_t *port_handlep) { struct xenisrc *isrc; KASSERT(port_handlep != NULL, ("NULL xen_intr_handle_t passed to %s", __func__)); isrc = xen_intr_isrc_from_handle(*port_handlep); *port_handlep = NULL; if (isrc == NULL) return; mtx_lock(&xen_intr_isrc_lock); if (refcount_release(&isrc->xi_refcount) == 0) { mtx_unlock(&xen_intr_isrc_lock); return; } mtx_unlock(&xen_intr_isrc_lock); if (isrc->xi_cookie != NULL) xen_arch_intr_remove_handler(isrc, isrc->xi_cookie); xen_intr_release_isrc(isrc); } void xen_intr_signal(xen_intr_handle_t handle) { struct xenisrc *isrc; isrc = xen_intr_isrc_from_handle(handle); if (isrc != NULL) { KASSERT(isrc->xi_type == EVTCHN_TYPE_PORT || isrc->xi_type == EVTCHN_TYPE_IPI, ("evtchn_signal on something other than a local port")); struct evtchn_send send = { .port = isrc->xi_port }; (void)HYPERVISOR_event_channel_op(EVTCHNOP_send, &send); } } evtchn_port_t xen_intr_port(xen_intr_handle_t handle) { struct xenisrc *isrc; isrc = xen_intr_isrc_from_handle(handle); if (isrc == NULL) return (0); return (isrc->xi_port); } int xen_intr_add_handler(const char *name, driver_filter_t filter, driver_intr_t handler, void *arg, enum intr_type flags, xen_intr_handle_t handle) { struct xenisrc *isrc; int error; isrc = xen_intr_isrc_from_handle(handle); if (isrc == NULL || isrc->xi_cookie != NULL) return (EINVAL); error = xen_arch_intr_add_handler(name, filter, handler, arg, flags | INTR_EXCL, isrc, &isrc->xi_cookie); if (error != 0) printf("%s: %s: add handler failed: %d\n", name, __func__, error); return (error); } int xen_intr_get_evtchn_from_port(evtchn_port_t port, xen_intr_handle_t *handlep) { if (!is_valid_evtchn(port)) return (EINVAL); if (handlep == NULL) { return (EINVAL); } mtx_lock(&xen_intr_isrc_lock); if (xen_intr_port_to_isrc[port] == NULL) { mtx_unlock(&xen_intr_isrc_lock); return (EINVAL); } refcount_acquire(&xen_intr_port_to_isrc[port]->xi_refcount); mtx_unlock(&xen_intr_isrc_lock); /* Assign the opaque handler */ *handlep = xen_intr_handle_from_isrc(xen_intr_port_to_isrc[port]); return (0); } #ifdef DDB static const char * xen_intr_print_type(enum evtchn_type type) { static const char *evtchn_type_to_string[EVTCHN_TYPE_COUNT] = { [EVTCHN_TYPE_UNBOUND] = "UNBOUND", [EVTCHN_TYPE_VIRQ] = "VIRQ", [EVTCHN_TYPE_IPI] = "IPI", [EVTCHN_TYPE_PORT] = "PORT", }; if (type >= EVTCHN_TYPE_COUNT) return ("UNKNOWN"); return (evtchn_type_to_string[type]); } static void xen_intr_dump_port(struct xenisrc *isrc) { struct xen_intr_pcpu_data *pcpu; shared_info_t *s = HYPERVISOR_shared_info; u_int i; db_printf("Port %d Type: %s\n", isrc->xi_port, xen_intr_print_type(isrc->xi_type)); if (isrc->xi_type == EVTCHN_TYPE_VIRQ) db_printf("\tVirq: %u\n", isrc->xi_virq); db_printf("\tMasked: %d Pending: %d\n", !!xen_test_bit(isrc->xi_port, &s->evtchn_mask[0]), !!xen_test_bit(isrc->xi_port, &s->evtchn_pending[0])); db_printf("\tPer-CPU Masks: "); CPU_FOREACH(i) { pcpu = DPCPU_ID_PTR(i, xen_intr_pcpu); db_printf("cpu#%u: %d ", i, !!xen_test_bit(isrc->xi_port, pcpu->evtchn_enabled)); } db_printf("\n"); } DB_SHOW_COMMAND(xen_evtchn, db_show_xen_evtchn) { u_int i; if (!xen_domain()) { db_printf("Only available on Xen guests\n"); return; } for (i = 0; i < NR_EVENT_CHANNELS; i++) { struct xenisrc *isrc; isrc = xen_intr_port_to_isrc[i]; if (isrc == NULL) continue; xen_intr_dump_port(isrc); } } #endif /* DDB */