/* $OpenBSD: xen.c,v 1.93 2018/01/21 18:54:46 mikeb Exp $ */ /* * Copyright (c) 2015, 2016, 2017 Mike Belopuhov * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include /* Xen requires locked atomic operations */ #ifndef MULTIPROCESSOR #define _XENMPATOMICS #define MULTIPROCESSOR #endif #include #ifdef _XENMPATOMICS #undef MULTIPROCESSOR #undef _XENMPATOMICS #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* #define XEN_DEBUG */ #ifdef XEN_DEBUG #define DPRINTF(x...) printf(x) #else #define DPRINTF(x...) #endif struct xen_softc *xen_sc; int xen_init_hypercall(struct xen_softc *); int xen_getfeatures(struct xen_softc *); int xen_init_info_page(struct xen_softc *); int xen_init_cbvec(struct xen_softc *); int xen_init_interrupts(struct xen_softc *); void xen_intr_dispatch(void *); int xen_init_grant_tables(struct xen_softc *); struct xen_gntent * xen_grant_table_grow(struct xen_softc *); int xen_grant_table_alloc(struct xen_softc *, grant_ref_t *); void xen_grant_table_free(struct xen_softc *, grant_ref_t); void xen_grant_table_enter(struct xen_softc *, grant_ref_t, paddr_t, int, int); void xen_grant_table_remove(struct xen_softc *, grant_ref_t); void xen_disable_emulated_devices(struct xen_softc *); int xen_match(struct device *, void *, void *); void xen_attach(struct device *, struct device *, void *); void xen_deferred(struct device *); void xen_control(void *); void xen_hotplug(void *); void xen_resume(struct device *); int xen_activate(struct device *, int); int xen_attach_device(struct xen_softc *, struct xen_devlist *, const char *, const char *); int xen_probe_devices(struct xen_softc *); int xen_bus_dmamap_create(bus_dma_tag_t, bus_size_t, int, bus_size_t, bus_size_t, int, bus_dmamap_t *); void xen_bus_dmamap_destroy(bus_dma_tag_t, bus_dmamap_t); int xen_bus_dmamap_load(bus_dma_tag_t, bus_dmamap_t, void *, bus_size_t, struct proc *, int); int xen_bus_dmamap_load_mbuf(bus_dma_tag_t, bus_dmamap_t, struct mbuf *, int); void xen_bus_dmamap_unload(bus_dma_tag_t, bus_dmamap_t); void xen_bus_dmamap_sync(bus_dma_tag_t, bus_dmamap_t, bus_addr_t, bus_size_t, int); int xs_attach(struct xen_softc *); struct cfdriver xen_cd = { NULL, "xen", DV_DULL }; const struct cfattach xen_ca = { sizeof(struct xen_softc), xen_match, xen_attach, NULL, xen_activate }; struct bus_dma_tag xen_bus_dma_tag = { NULL, xen_bus_dmamap_create, xen_bus_dmamap_destroy, xen_bus_dmamap_load, xen_bus_dmamap_load_mbuf, NULL, NULL, xen_bus_dmamap_unload, xen_bus_dmamap_sync, _bus_dmamem_alloc, NULL, _bus_dmamem_free, _bus_dmamem_map, _bus_dmamem_unmap, NULL, }; int xen_match(struct device *parent, void *match, void *aux) { struct pv_attach_args *pva = aux; struct pvbus_hv *hv = &pva->pva_hv[PVBUS_XEN]; if (hv->hv_base == 0) return (0); return (1); } void xen_attach(struct device *parent, struct device *self, void *aux) { struct pv_attach_args *pva = (struct pv_attach_args *)aux; struct pvbus_hv *hv = &pva->pva_hv[PVBUS_XEN]; struct xen_softc *sc = (struct xen_softc *)self; sc->sc_base = hv->hv_base; sc->sc_dmat = pva->pva_dmat; if (xen_init_hypercall(sc)) return; /* Wire it up to the global */ xen_sc = sc; if (xen_getfeatures(sc)) return; if (xen_init_info_page(sc)) return; xen_init_cbvec(sc); if (xen_init_interrupts(sc)) return; if (xen_init_grant_tables(sc)) return; if (xs_attach(sc)) return; xen_probe_devices(sc); /* pvbus(4) key/value interface */ hv->hv_kvop = xs_kvop; hv->hv_arg = sc; xen_disable_emulated_devices(sc); config_mountroot(self, xen_deferred); } void xen_deferred(struct device *self) { struct xen_softc *sc = (struct xen_softc *)self; if (!(sc->sc_flags & XSF_CBVEC)) { DPRINTF("%s: callback vector hasn't been established\n", sc->sc_dev.dv_xname); return; } xen_intr_enable(); if (xs_watch(sc, "control", "shutdown", &sc->sc_ctltsk, xen_control, sc)) printf("%s: failed to setup shutdown control watch\n", sc->sc_dev.dv_xname); } void xen_control(void *arg) { struct xen_softc *sc = arg; struct xs_transaction xst; char action[128]; int error; memset(&xst, 0, sizeof(xst)); xst.xst_id = 0; xst.xst_cookie = sc->sc_xs; error = xs_getprop(sc, "control", "shutdown", action, sizeof(action)); if (error) { if (error != ENOENT) printf("%s: failed to process control event\n", sc->sc_dev.dv_xname); return; } if (strlen(action) == 0) return; /* Acknowledge the event */ xs_setprop(sc, "control", "shutdown", "", 0); if (strcmp(action, "halt") == 0 || strcmp(action, "poweroff") == 0) { pvbus_shutdown(&sc->sc_dev); } else if (strcmp(action, "reboot") == 0) { pvbus_reboot(&sc->sc_dev); } else if (strcmp(action, "crash") == 0) { panic("xen told us to do this"); } else if (strcmp(action, "suspend") == 0) { /* Not implemented yet */ } else { printf("%s: unknown shutdown event \"%s\"\n", sc->sc_dev.dv_xname, action); } } void xen_resume(struct device *self) { } int xen_activate(struct device *self, int act) { int rv = 0; switch (act) { case DVACT_RESUME: xen_resume(self); break; } return (rv); } int xen_init_hypercall(struct xen_softc *sc) { extern void *xen_hypercall_page; uint32_t regs[4]; paddr_t pa; /* Get hypercall page configuration MSR */ CPUID(sc->sc_base + CPUID_OFFSET_XEN_HYPERCALL, regs[0], regs[1], regs[2], regs[3]); /* We don't support more than one hypercall page */ if (regs[0] != 1) { printf(": requested %u hypercall pages\n", regs[0]); return (-1); } sc->sc_hc = &xen_hypercall_page; if (!pmap_extract(pmap_kernel(), (vaddr_t)sc->sc_hc, &pa)) { printf(": hypercall page PA extraction failed\n"); return (-1); } wrmsr(regs[1], pa); return (0); } int xen_hypercall(struct xen_softc *sc, int op, int argc, ...) { va_list ap; ulong argv[5]; int i; if (argc < 0 || argc > 5) return (-1); va_start(ap, argc); for (i = 0; i < argc; i++) argv[i] = (ulong)va_arg(ap, ulong); va_end(ap); return (xen_hypercallv(sc, op, argc, argv)); } int xen_hypercallv(struct xen_softc *sc, int op, int argc, ulong *argv) { ulong hcall; int rv = 0; hcall = (ulong)sc->sc_hc + op * 32; #if defined(XEN_DEBUG) && disabled { int i; printf("hypercall %d", op); if (argc > 0) { printf(", args {"); for (i = 0; i < argc; i++) printf(" %#lx", argv[i]); printf(" }\n"); } else printf("\n"); } #endif switch (argc) { case 0: { HYPERCALL_RES1; __asm__ volatile ( \ HYPERCALL_LABEL \ : HYPERCALL_OUT1 \ : HYPERCALL_PTR(hcall) \ : HYPERCALL_CLOBBER \ ); HYPERCALL_RET(rv); break; } case 1: { HYPERCALL_RES1; HYPERCALL_RES2; HYPERCALL_ARG1(argv[0]); __asm__ volatile ( \ HYPERCALL_LABEL \ : HYPERCALL_OUT1 HYPERCALL_OUT2 \ : HYPERCALL_IN1 \ , HYPERCALL_PTR(hcall) \ : HYPERCALL_CLOBBER \ ); HYPERCALL_RET(rv); break; } case 2: { HYPERCALL_RES1; HYPERCALL_RES2; HYPERCALL_RES3; HYPERCALL_ARG1(argv[0]); HYPERCALL_ARG2(argv[1]); __asm__ volatile ( \ HYPERCALL_LABEL \ : HYPERCALL_OUT1 HYPERCALL_OUT2 \ HYPERCALL_OUT3 \ : HYPERCALL_IN1 HYPERCALL_IN2 \ , HYPERCALL_PTR(hcall) \ : HYPERCALL_CLOBBER \ ); HYPERCALL_RET(rv); break; } case 3: { HYPERCALL_RES1; HYPERCALL_RES2; HYPERCALL_RES3; HYPERCALL_RES4; HYPERCALL_ARG1(argv[0]); HYPERCALL_ARG2(argv[1]); HYPERCALL_ARG3(argv[2]); __asm__ volatile ( \ HYPERCALL_LABEL \ : HYPERCALL_OUT1 HYPERCALL_OUT2 \ HYPERCALL_OUT3 HYPERCALL_OUT4 \ : HYPERCALL_IN1 HYPERCALL_IN2 \ HYPERCALL_IN3 \ , HYPERCALL_PTR(hcall) \ : HYPERCALL_CLOBBER \ ); HYPERCALL_RET(rv); break; } case 4: { HYPERCALL_RES1; HYPERCALL_RES2; HYPERCALL_RES3; HYPERCALL_RES4; HYPERCALL_RES5; HYPERCALL_ARG1(argv[0]); HYPERCALL_ARG2(argv[1]); HYPERCALL_ARG3(argv[2]); HYPERCALL_ARG4(argv[3]); __asm__ volatile ( \ HYPERCALL_LABEL \ : HYPERCALL_OUT1 HYPERCALL_OUT2 \ HYPERCALL_OUT3 HYPERCALL_OUT4 \ HYPERCALL_OUT5 \ : HYPERCALL_IN1 HYPERCALL_IN2 \ HYPERCALL_IN3 HYPERCALL_IN4 \ , HYPERCALL_PTR(hcall) \ : HYPERCALL_CLOBBER \ ); HYPERCALL_RET(rv); break; } case 5: { HYPERCALL_RES1; HYPERCALL_RES2; HYPERCALL_RES3; HYPERCALL_RES4; HYPERCALL_RES5; HYPERCALL_RES6; HYPERCALL_ARG1(argv[0]); HYPERCALL_ARG2(argv[1]); HYPERCALL_ARG3(argv[2]); HYPERCALL_ARG4(argv[3]); HYPERCALL_ARG5(argv[4]); __asm__ volatile ( \ HYPERCALL_LABEL \ : HYPERCALL_OUT1 HYPERCALL_OUT2 \ HYPERCALL_OUT3 HYPERCALL_OUT4 \ HYPERCALL_OUT5 HYPERCALL_OUT6 \ : HYPERCALL_IN1 HYPERCALL_IN2 \ HYPERCALL_IN3 HYPERCALL_IN4 \ HYPERCALL_IN5 \ , HYPERCALL_PTR(hcall) \ : HYPERCALL_CLOBBER \ ); HYPERCALL_RET(rv); break; } default: DPRINTF("%s: wrong number of arguments: %d\n", __func__, argc); rv = -1; break; } return (rv); } int xen_getfeatures(struct xen_softc *sc) { struct xen_feature_info xfi; memset(&xfi, 0, sizeof(xfi)); if (xen_hypercall(sc, XC_VERSION, 2, XENVER_get_features, &xfi) < 0) { printf(": failed to fetch features\n"); return (-1); } sc->sc_features = xfi.submap; #ifdef XEN_DEBUG printf(": features %b", sc->sc_features, "\20\014DOM0\013PIRQ\012PVCLOCK\011CBVEC\010GNTFLAGS\007HMA" "\006PTUPD\005PAE4G\004SUPERVISOR\003AUTOPMAP\002WDT\001WPT"); #else printf(": features %#x", sc->sc_features); #endif return (0); } #ifdef XEN_DEBUG void xen_print_info_page(void) { struct xen_softc *sc = xen_sc; struct shared_info *s = sc->sc_ipg; struct vcpu_info *v; int i; virtio_membar_sync(); for (i = 0; i < XEN_LEGACY_MAX_VCPUS; i++) { v = &s->vcpu_info[i]; if (!v->evtchn_upcall_pending && !v->evtchn_upcall_mask && !v->evtchn_pending_sel && !v->time.version && !v->time.tsc_timestamp && !v->time.system_time && !v->time.tsc_to_system_mul && !v->time.tsc_shift) continue; printf("vcpu%d:\n" " upcall_pending=%02x upcall_mask=%02x pending_sel=%#lx\n" " time version=%u tsc=%llu system=%llu\n" " time mul=%u shift=%d\n", i, v->evtchn_upcall_pending, v->evtchn_upcall_mask, v->evtchn_pending_sel, v->time.version, v->time.tsc_timestamp, v->time.system_time, v->time.tsc_to_system_mul, v->time.tsc_shift); } printf("pending events: "); for (i = 0; i < nitems(s->evtchn_pending); i++) { if (s->evtchn_pending[i] == 0) continue; printf(" %d:%#lx", i, s->evtchn_pending[i]); } printf("\nmasked events: "); for (i = 0; i < nitems(s->evtchn_mask); i++) { if (s->evtchn_mask[i] == 0xffffffffffffffffULL) continue; printf(" %d:%#lx", i, s->evtchn_mask[i]); } printf("\nwc ver=%u sec=%u nsec=%u\n", s->wc_version, s->wc_sec, s->wc_nsec); printf("arch maxpfn=%lu framelist=%lu nmi=%lu\n", s->arch.max_pfn, s->arch.pfn_to_mfn_frame_list, s->arch.nmi_reason); } #endif /* XEN_DEBUG */ int xen_init_info_page(struct xen_softc *sc) { struct xen_add_to_physmap xatp; paddr_t pa; sc->sc_ipg = malloc(PAGE_SIZE, M_DEVBUF, M_NOWAIT | M_ZERO); if (sc->sc_ipg == NULL) { printf(": failed to allocate shared info page\n"); return (-1); } if (!pmap_extract(pmap_kernel(), (vaddr_t)sc->sc_ipg, &pa)) { printf(": shared info page PA extraction failed\n"); free(sc->sc_ipg, M_DEVBUF, PAGE_SIZE); return (-1); } xatp.domid = DOMID_SELF; xatp.idx = 0; xatp.space = XENMAPSPACE_shared_info; xatp.gpfn = atop(pa); if (xen_hypercall(sc, XC_MEMORY, 2, XENMEM_add_to_physmap, &xatp)) { printf(": failed to register shared info page\n"); free(sc->sc_ipg, M_DEVBUF, PAGE_SIZE); return (-1); } return (0); } int xen_init_cbvec(struct xen_softc *sc) { struct xen_hvm_param xhp; if ((sc->sc_features & XENFEAT_CBVEC) == 0) return (ENOENT); xhp.domid = DOMID_SELF; xhp.index = HVM_PARAM_CALLBACK_IRQ; xhp.value = HVM_CALLBACK_VECTOR(LAPIC_XEN_VECTOR); if (xen_hypercall(sc, XC_HVM, 2, HVMOP_set_param, &xhp)) { /* Will retry with the xspd(4) PCI interrupt */ return (ENOENT); } DPRINTF(", idtvec %d", LAPIC_XEN_VECTOR); sc->sc_flags |= XSF_CBVEC; return (0); } int xen_init_interrupts(struct xen_softc *sc) { int i; sc->sc_irq = LAPIC_XEN_VECTOR; /* * Clear all pending events and mask all interrupts */ for (i = 0; i < nitems(sc->sc_ipg->evtchn_pending); i++) { sc->sc_ipg->evtchn_pending[i] = 0; sc->sc_ipg->evtchn_mask[i] = ~0UL; } SLIST_INIT(&sc->sc_intrs); mtx_init(&sc->sc_islck, IPL_NET); return (0); } static int xen_evtchn_hypercall(struct xen_softc *sc, int cmd, void *arg, size_t len) { struct evtchn_op compat; int error; error = xen_hypercall(sc, XC_EVTCHN, 2, cmd, arg); if (error == -ENOXENSYS) { memset(&compat, 0, sizeof(compat)); compat.cmd = cmd; memcpy(&compat.u, arg, len); error = xen_hypercall(sc, XC_OEVTCHN, 1, &compat); } return (error); } static inline void xen_intsrc_add(struct xen_softc *sc, struct xen_intsrc *xi) { refcnt_init(&xi->xi_refcnt); mtx_enter(&sc->sc_islck); SLIST_INSERT_HEAD(&sc->sc_intrs, xi, xi_entry); mtx_leave(&sc->sc_islck); } static inline struct xen_intsrc * xen_intsrc_acquire(struct xen_softc *sc, evtchn_port_t port) { struct xen_intsrc *xi = NULL; mtx_enter(&sc->sc_islck); SLIST_FOREACH(xi, &sc->sc_intrs, xi_entry) { if (xi->xi_port == port) { refcnt_take(&xi->xi_refcnt); break; } } mtx_leave(&sc->sc_islck); return (xi); } static inline void xen_intsrc_release(struct xen_softc *sc, struct xen_intsrc *xi) { refcnt_rele_wake(&xi->xi_refcnt); } static inline struct xen_intsrc * xen_intsrc_remove(struct xen_softc *sc, evtchn_port_t port) { struct xen_intsrc *xi; mtx_enter(&sc->sc_islck); SLIST_FOREACH(xi, &sc->sc_intrs, xi_entry) { if (xi->xi_port == port) { SLIST_REMOVE(&sc->sc_intrs, xi, xen_intsrc, xi_entry); break; } } mtx_leave(&sc->sc_islck); if (xi != NULL) refcnt_finalize(&xi->xi_refcnt, "xenisrm"); return (xi); } static inline void xen_intr_mask_acquired(struct xen_softc *sc, struct xen_intsrc *xi) { xi->xi_masked = 1; set_bit(xi->xi_port, &sc->sc_ipg->evtchn_mask[0]); } static inline int xen_intr_unmask_release(struct xen_softc *sc, struct xen_intsrc *xi) { struct evtchn_unmask eu; xi->xi_masked = 0; if (!test_bit(xi->xi_port, &sc->sc_ipg->evtchn_mask[0])) return (0); eu.port = xi->xi_port; xen_intsrc_release(sc, xi); return (xen_evtchn_hypercall(sc, EVTCHNOP_unmask, &eu, sizeof(eu))); } void xen_intr_ack(void) { struct xen_softc *sc = xen_sc; struct shared_info *s = sc->sc_ipg; struct cpu_info *ci = curcpu(); struct vcpu_info *v = &s->vcpu_info[CPU_INFO_UNIT(ci)]; v->evtchn_upcall_pending = 0; virtio_membar_sync(); } void xen_intr(void) { struct xen_softc *sc = xen_sc; struct xen_intsrc *xi; struct shared_info *s = sc->sc_ipg; struct cpu_info *ci = curcpu(); struct vcpu_info *v = &s->vcpu_info[CPU_INFO_UNIT(ci)]; ulong pending, selector; int port, bit, row; v->evtchn_upcall_pending = 0; selector = atomic_swap_ulong(&v->evtchn_pending_sel, 0); for (row = 0; selector > 0; selector >>= 1, row++) { if ((selector & 1) == 0) continue; if ((sc->sc_ipg->evtchn_pending[row] & ~(sc->sc_ipg->evtchn_mask[row])) == 0) continue; pending = atomic_swap_ulong(&sc->sc_ipg->evtchn_pending[row], 0) & ~(sc->sc_ipg->evtchn_mask[row]); for (bit = 0; pending > 0; pending >>= 1, bit++) { if ((pending & 1) == 0) continue; port = (row * LONG_BIT) + bit; if ((xi = xen_intsrc_acquire(sc, port)) == NULL) { printf("%s: unhandled interrupt on port %d\n", sc->sc_dev.dv_xname, port); continue; } xi->xi_evcnt.ec_count++; xen_intr_mask_acquired(sc, xi); task_add(xi->xi_taskq, &xi->xi_task); } } } void xen_intr_schedule(xen_intr_handle_t xih) { struct xen_softc *sc = xen_sc; struct xen_intsrc *xi; if ((xi = xen_intsrc_acquire(sc, (evtchn_port_t)xih)) != NULL) { if (!task_add(xi->xi_taskq, &xi->xi_task)) xen_intsrc_release(sc, xi); } } /* * This code achieves two goals: 1) makes sure that *after* masking * the interrupt source we're not getting more task_adds: intr_barrier * will take care of that, and 2) makes sure that the interrupt task * has finished executing the current task and won't be called again: * it sets up a barrier task to await completion of the current task * and relies on the interrupt masking to prevent submission of new * tasks in the future. */ void xen_intr_barrier(xen_intr_handle_t xih) { struct xen_softc *sc = xen_sc; struct xen_intsrc *xi; /* * XXX This will need to be revised once intr_barrier starts * using its argument. */ intr_barrier(NULL); if ((xi = xen_intsrc_acquire(sc, (evtchn_port_t)xih)) != NULL) { taskq_barrier(xi->xi_taskq); xen_intsrc_release(sc, xi); } } void xen_intr_signal(xen_intr_handle_t xih) { struct xen_softc *sc = xen_sc; struct xen_intsrc *xi; struct evtchn_send es; if ((xi = xen_intsrc_acquire(sc, (evtchn_port_t)xih)) != NULL) { es.port = xi->xi_port; xen_intsrc_release(sc, xi); xen_evtchn_hypercall(sc, EVTCHNOP_send, &es, sizeof(es)); } } int xen_intr_establish(evtchn_port_t port, xen_intr_handle_t *xih, int domain, void (*handler)(void *), void *arg, char *name) { struct xen_softc *sc = xen_sc; struct xen_intsrc *xi; struct evtchn_alloc_unbound eau; #ifdef notyet struct evtchn_bind_vcpu ebv; #endif #if defined(XEN_DEBUG) && disabled struct evtchn_status es; #endif if (port && (xi = xen_intsrc_acquire(sc, port)) != NULL) { xen_intsrc_release(sc, xi); DPRINTF("%s: interrupt handler has already been established " "for port %u\n", sc->sc_dev.dv_xname, port); return (-1); } xi = malloc(sizeof(*xi), M_DEVBUF, M_NOWAIT | M_ZERO); if (xi == NULL) return (-1); xi->xi_port = (evtchn_port_t)*xih; xi->xi_handler = handler; xi->xi_ctx = arg; xi->xi_taskq = taskq_create(name, 1, IPL_NET, TASKQ_MPSAFE); if (!xi->xi_taskq) { printf("%s: failed to create interrupt task for %s\n", sc->sc_dev.dv_xname, name); free(xi, M_DEVBUF, sizeof(*xi)); return (-1); } task_set(&xi->xi_task, xen_intr_dispatch, xi); if (port == 0) { /* We're being asked to allocate a new event port */ memset(&eau, 0, sizeof(eau)); eau.dom = DOMID_SELF; eau.remote_dom = domain; if (xen_evtchn_hypercall(sc, EVTCHNOP_alloc_unbound, &eau, sizeof(eau)) != 0) { DPRINTF("%s: failed to allocate new event port\n", sc->sc_dev.dv_xname); free(xi, M_DEVBUF, sizeof(*xi)); return (-1); } *xih = xi->xi_port = eau.port; } else { *xih = xi->xi_port = port; /* * The Event Channel API didn't open this port, so it is not * responsible for closing it automatically on unbind. */ xi->xi_noclose = 1; } #ifdef notyet /* Bind interrupt to VCPU#0 */ memset(&ebv, 0, sizeof(ebv)); ebv.port = xi->xi_port; ebv.vcpu = 0; if (xen_evtchn_hypercall(sc, EVTCHNOP_bind_vcpu, &ebv, sizeof(ebv))) { printf("%s: failed to bind interrupt on port %u to vcpu%d\n", sc->sc_dev.dv_xname, ebv.port, ebv.vcpu); } #endif evcount_attach(&xi->xi_evcnt, name, &sc->sc_irq); xen_intsrc_add(sc, xi); /* Mask the event port */ set_bit(xi->xi_port, &sc->sc_ipg->evtchn_mask[0]); #if defined(XEN_DEBUG) && disabled memset(&es, 0, sizeof(es)); es.dom = DOMID_SELF; es.port = xi->xi_port; if (xen_evtchn_hypercall(sc, EVTCHNOP_status, &es, sizeof(es))) { printf("%s: failed to obtain status for port %d\n", sc->sc_dev.dv_xname, es.port); } printf("%s: port %u bound to vcpu%u", sc->sc_dev.dv_xname, es.port, es.vcpu); if (es.status == EVTCHNSTAT_interdomain) printf(": domain %d port %u\n", es.u.interdomain.dom, es.u.interdomain.port); else if (es.status == EVTCHNSTAT_unbound) printf(": domain %d\n", es.u.unbound.dom); else if (es.status == EVTCHNSTAT_pirq) printf(": pirq %u\n", es.u.pirq); else if (es.status == EVTCHNSTAT_virq) printf(": virq %u\n", es.u.virq); else printf("\n"); #endif return (0); } int xen_intr_disestablish(xen_intr_handle_t xih) { struct xen_softc *sc = xen_sc; evtchn_port_t port = (evtchn_port_t)xih; struct evtchn_close ec; struct xen_intsrc *xi; if ((xi = xen_intsrc_remove(sc, port)) == NULL) return (-1); evcount_detach(&xi->xi_evcnt); taskq_destroy(xi->xi_taskq); set_bit(xi->xi_port, &sc->sc_ipg->evtchn_mask[0]); clear_bit(xi->xi_port, &sc->sc_ipg->evtchn_pending[0]); if (!xi->xi_noclose) { ec.port = xi->xi_port; if (xen_evtchn_hypercall(sc, EVTCHNOP_close, &ec, sizeof(ec))) { DPRINTF("%s: failed to close event port %u\n", sc->sc_dev.dv_xname, xi->xi_port); } } free(xi, M_DEVBUF, sizeof(*xi)); return (0); } void xen_intr_dispatch(void *arg) { struct xen_softc *sc = xen_sc; struct xen_intsrc *xi = arg; if (xi->xi_handler) xi->xi_handler(xi->xi_ctx); xen_intr_unmask_release(sc, xi); } void xen_intr_enable(void) { struct xen_softc *sc = xen_sc; struct xen_intsrc *xi; struct evtchn_unmask eu; mtx_enter(&sc->sc_islck); SLIST_FOREACH(xi, &sc->sc_intrs, xi_entry) { if (!xi->xi_masked) { eu.port = xi->xi_port; if (xen_evtchn_hypercall(sc, EVTCHNOP_unmask, &eu, sizeof(eu))) printf("%s: unmasking port %u failed\n", sc->sc_dev.dv_xname, xi->xi_port); virtio_membar_sync(); if (test_bit(xi->xi_port, &sc->sc_ipg->evtchn_mask[0])) printf("%s: port %u is still masked\n", sc->sc_dev.dv_xname, xi->xi_port); } } mtx_leave(&sc->sc_islck); } void xen_intr_mask(xen_intr_handle_t xih) { struct xen_softc *sc = xen_sc; evtchn_port_t port = (evtchn_port_t)xih; struct xen_intsrc *xi; if ((xi = xen_intsrc_acquire(sc, port)) != NULL) { xen_intr_mask_acquired(sc, xi); xen_intsrc_release(sc, xi); } } int xen_intr_unmask(xen_intr_handle_t xih) { struct xen_softc *sc = xen_sc; evtchn_port_t port = (evtchn_port_t)xih; struct xen_intsrc *xi; if ((xi = xen_intsrc_acquire(sc, port)) != NULL) return (xen_intr_unmask_release(sc, xi)); return (0); } int xen_init_grant_tables(struct xen_softc *sc) { struct gnttab_query_size gqs; gqs.dom = DOMID_SELF; if (xen_hypercall(sc, XC_GNTTAB, 3, GNTTABOP_query_size, &gqs, 1)) { printf(": failed the query for grant table pages\n"); return (-1); } if (gqs.nr_frames == 0 || gqs.nr_frames > gqs.max_nr_frames) { printf(": invalid number of grant table pages: %u/%u\n", gqs.nr_frames, gqs.max_nr_frames); return (-1); } sc->sc_gntmax = gqs.max_nr_frames; sc->sc_gnt = mallocarray(sc->sc_gntmax + 1, sizeof(struct xen_gntent), M_DEVBUF, M_ZERO | M_NOWAIT); if (sc->sc_gnt == NULL) { printf(": failed to allocate grant table lookup table\n"); return (-1); } mtx_init(&sc->sc_gntlck, IPL_NET); if (xen_grant_table_grow(sc) == NULL) { free(sc->sc_gnt, M_DEVBUF, sc->sc_gntmax * sizeof(struct xen_gntent)); return (-1); } printf(", %d grant table frames", sc->sc_gntmax); xen_bus_dma_tag._cookie = sc; return (0); } struct xen_gntent * xen_grant_table_grow(struct xen_softc *sc) { struct xen_add_to_physmap xatp; struct xen_gntent *ge; void *va; paddr_t pa; if (sc->sc_gntcnt == sc->sc_gntmax) { printf("%s: grant table frame allotment limit reached\n", sc->sc_dev.dv_xname); return (NULL); } va = km_alloc(PAGE_SIZE, &kv_any, &kp_zero, &kd_nowait); if (va == NULL) return (NULL); if (!pmap_extract(pmap_kernel(), (vaddr_t)va, &pa)) { printf("%s: grant table page PA extraction failed\n", sc->sc_dev.dv_xname); km_free(va, PAGE_SIZE, &kv_any, &kp_zero); return (NULL); } mtx_enter(&sc->sc_gntlck); ge = &sc->sc_gnt[sc->sc_gntcnt]; ge->ge_table = va; xatp.domid = DOMID_SELF; xatp.idx = sc->sc_gntcnt; xatp.space = XENMAPSPACE_grant_table; xatp.gpfn = atop(pa); if (xen_hypercall(sc, XC_MEMORY, 2, XENMEM_add_to_physmap, &xatp)) { printf("%s: failed to add a grant table page\n", sc->sc_dev.dv_xname); km_free(ge->ge_table, PAGE_SIZE, &kv_any, &kp_zero); mtx_leave(&sc->sc_gntlck); return (NULL); } ge->ge_start = sc->sc_gntcnt * GNTTAB_NEPG; /* First page has 8 reserved entries */ ge->ge_reserved = ge->ge_start == 0 ? GNTTAB_NR_RESERVED_ENTRIES : 0; ge->ge_free = GNTTAB_NEPG - ge->ge_reserved; ge->ge_next = ge->ge_reserved; mtx_init(&ge->ge_lock, IPL_NET); sc->sc_gntcnt++; mtx_leave(&sc->sc_gntlck); return (ge); } int xen_grant_table_alloc(struct xen_softc *sc, grant_ref_t *ref) { struct xen_gntent *ge; int i; /* Start with a previously allocated table page */ ge = &sc->sc_gnt[sc->sc_gntcnt - 1]; if (ge->ge_free > 0) { mtx_enter(&ge->ge_lock); if (ge->ge_free > 0) goto search; mtx_leave(&ge->ge_lock); } /* Try other existing table pages */ for (i = 0; i < sc->sc_gntcnt; i++) { ge = &sc->sc_gnt[i]; if (ge->ge_free == 0) continue; mtx_enter(&ge->ge_lock); if (ge->ge_free > 0) goto search; mtx_leave(&ge->ge_lock); } alloc: /* Allocate a new table page */ if ((ge = xen_grant_table_grow(sc)) == NULL) return (-1); mtx_enter(&ge->ge_lock); if (ge->ge_free == 0) { /* We were not fast enough... */ mtx_leave(&ge->ge_lock); goto alloc; } search: for (i = ge->ge_next; /* Math works here because GNTTAB_NEPG is a power of 2 */ i != ((ge->ge_next + GNTTAB_NEPG - 1) & (GNTTAB_NEPG - 1)); i++) { if (i == GNTTAB_NEPG) i = 0; if (ge->ge_reserved && i < ge->ge_reserved) continue; if (ge->ge_table[i].frame != 0) continue; *ref = ge->ge_start + i; ge->ge_table[i].flags = GTF_invalid; ge->ge_table[i].frame = 0xffffffff; /* Mark as taken */ if ((ge->ge_next = i + 1) == GNTTAB_NEPG) ge->ge_next = ge->ge_reserved; ge->ge_free--; mtx_leave(&ge->ge_lock); return (0); } mtx_leave(&ge->ge_lock); panic("page full, sc %p gnt %p (%d) ge %p", sc, sc->sc_gnt, sc->sc_gntcnt, ge); return (-1); } void xen_grant_table_free(struct xen_softc *sc, grant_ref_t ref) { struct xen_gntent *ge; #ifdef XEN_DEBUG if (ref > sc->sc_gntcnt * GNTTAB_NEPG) panic("unmanaged ref %u sc %p gnt %p (%d)", ref, sc, sc->sc_gnt, sc->sc_gntcnt); #endif ge = &sc->sc_gnt[ref / GNTTAB_NEPG]; mtx_enter(&ge->ge_lock); #ifdef XEN_DEBUG if (ref < ge->ge_start || ref > ge->ge_start + GNTTAB_NEPG) { mtx_leave(&ge->ge_lock); panic("out of bounds ref %u ge %p start %u sc %p gnt %p", ref, ge, ge->ge_start, sc, sc->sc_gnt); } #endif ref -= ge->ge_start; if (ge->ge_table[ref].flags != GTF_invalid) { mtx_leave(&ge->ge_lock); panic("reference %u is still in use, flags %#x frame %#x", ref + ge->ge_start, ge->ge_table[ref].flags, ge->ge_table[ref].frame); } ge->ge_table[ref].frame = 0; ge->ge_next = ref; ge->ge_free++; mtx_leave(&ge->ge_lock); } void xen_grant_table_enter(struct xen_softc *sc, grant_ref_t ref, paddr_t pa, int domain, int flags) { struct xen_gntent *ge; #ifdef XEN_DEBUG if (ref > sc->sc_gntcnt * GNTTAB_NEPG) panic("unmanaged ref %u sc %p gnt %p (%d)", ref, sc, sc->sc_gnt, sc->sc_gntcnt); #endif ge = &sc->sc_gnt[ref / GNTTAB_NEPG]; #ifdef XEN_DEBUG if (ref < ge->ge_start || ref > ge->ge_start + GNTTAB_NEPG) { panic("out of bounds ref %u ge %p start %u sc %p gnt %p", ref, ge, ge->ge_start, sc, sc->sc_gnt); } #endif ref -= ge->ge_start; if (ge->ge_table[ref].flags != GTF_invalid) { panic("reference %u is still in use, flags %#x frame %#x", ref + ge->ge_start, ge->ge_table[ref].flags, ge->ge_table[ref].frame); } ge->ge_table[ref].frame = atop(pa); ge->ge_table[ref].domid = domain; virtio_membar_sync(); ge->ge_table[ref].flags = GTF_permit_access | flags; virtio_membar_sync(); } void xen_grant_table_remove(struct xen_softc *sc, grant_ref_t ref) { struct xen_gntent *ge; uint32_t flags, *ptr; int loop; #ifdef XEN_DEBUG if (ref > sc->sc_gntcnt * GNTTAB_NEPG) panic("unmanaged ref %u sc %p gnt %p (%d)", ref, sc, sc->sc_gnt, sc->sc_gntcnt); #endif ge = &sc->sc_gnt[ref / GNTTAB_NEPG]; #ifdef XEN_DEBUG if (ref < ge->ge_start || ref > ge->ge_start + GNTTAB_NEPG) { panic("out of bounds ref %u ge %p start %u sc %p gnt %p", ref, ge, ge->ge_start, sc, sc->sc_gnt); } #endif ref -= ge->ge_start; /* Invalidate the grant reference */ virtio_membar_sync(); ptr = (uint32_t *)&ge->ge_table[ref]; flags = (ge->ge_table[ref].flags & ~(GTF_reading|GTF_writing)) | (ge->ge_table[ref].domid << 16); loop = 0; while (atomic_cas_uint(ptr, flags, GTF_invalid) != flags) { if (loop++ > 10) { panic("grant table reference %u is held " "by domain %d: frame %#x flags %#x", ref + ge->ge_start, ge->ge_table[ref].domid, ge->ge_table[ref].frame, ge->ge_table[ref].flags); } #if (defined(__amd64__) || defined(__i386__)) __asm volatile("pause": : : "memory"); #endif } ge->ge_table[ref].frame = 0xffffffff; } int xen_bus_dmamap_create(bus_dma_tag_t t, bus_size_t size, int nsegments, bus_size_t maxsegsz, bus_size_t boundary, int flags, bus_dmamap_t *dmamp) { struct xen_softc *sc = t->_cookie; struct xen_gntmap *gm; int i, error; if (maxsegsz < PAGE_SIZE) return (EINVAL); /* Allocate a dma map structure */ error = bus_dmamap_create(sc->sc_dmat, size, nsegments, maxsegsz, boundary, flags, dmamp); if (error) return (error); /* Allocate an array of grant table pa<->ref maps */ gm = mallocarray(nsegments, sizeof(struct xen_gntmap), M_DEVBUF, M_ZERO | ((flags & BUS_DMA_NOWAIT) ? M_NOWAIT : M_WAITOK)); if (gm == NULL) { bus_dmamap_destroy(sc->sc_dmat, *dmamp); *dmamp = NULL; return (ENOMEM); } /* Wire it to the dma map */ (*dmamp)->_dm_cookie = gm; /* Claim references from the grant table */ for (i = 0; i < (*dmamp)->_dm_segcnt; i++) { if (xen_grant_table_alloc(sc, &gm[i].gm_ref)) { xen_bus_dmamap_destroy(t, *dmamp); *dmamp = NULL; return (ENOBUFS); } } return (0); } void xen_bus_dmamap_destroy(bus_dma_tag_t t, bus_dmamap_t map) { struct xen_softc *sc = t->_cookie; struct xen_gntmap *gm; int i; gm = map->_dm_cookie; for (i = 0; i < map->_dm_segcnt; i++) { if (gm[i].gm_ref == 0) continue; xen_grant_table_free(sc, gm[i].gm_ref); } free(gm, M_DEVBUF, map->_dm_segcnt * sizeof(struct xen_gntmap)); bus_dmamap_destroy(sc->sc_dmat, map); } int xen_bus_dmamap_load(bus_dma_tag_t t, bus_dmamap_t map, void *buf, bus_size_t buflen, struct proc *p, int flags) { struct xen_softc *sc = t->_cookie; struct xen_gntmap *gm = map->_dm_cookie; int i, domain, error; domain = flags >> 16; flags &= 0xffff; error = bus_dmamap_load(sc->sc_dmat, map, buf, buflen, p, flags); if (error) return (error); for (i = 0; i < map->dm_nsegs; i++) { xen_grant_table_enter(sc, gm[i].gm_ref, map->dm_segs[i].ds_addr, domain, flags & BUS_DMA_WRITE ? GTF_readonly : 0); gm[i].gm_paddr = map->dm_segs[i].ds_addr; map->dm_segs[i].ds_addr = gm[i].gm_ref; } return (0); } int xen_bus_dmamap_load_mbuf(bus_dma_tag_t t, bus_dmamap_t map, struct mbuf *m0, int flags) { struct xen_softc *sc = t->_cookie; struct xen_gntmap *gm = map->_dm_cookie; int i, domain, error; domain = flags >> 16; flags &= 0xffff; error = bus_dmamap_load_mbuf(sc->sc_dmat, map, m0, flags); if (error) return (error); for (i = 0; i < map->dm_nsegs; i++) { xen_grant_table_enter(sc, gm[i].gm_ref, map->dm_segs[i].ds_addr, domain, flags & BUS_DMA_WRITE ? GTF_readonly : 0); gm[i].gm_paddr = map->dm_segs[i].ds_addr; map->dm_segs[i].ds_addr = gm[i].gm_ref; } return (0); } void xen_bus_dmamap_unload(bus_dma_tag_t t, bus_dmamap_t map) { struct xen_softc *sc = t->_cookie; struct xen_gntmap *gm = map->_dm_cookie; int i; for (i = 0; i < map->dm_nsegs; i++) { if (gm[i].gm_paddr == 0) continue; xen_grant_table_remove(sc, gm[i].gm_ref); map->dm_segs[i].ds_addr = gm[i].gm_paddr; gm[i].gm_paddr = 0; } bus_dmamap_unload(sc->sc_dmat, map); } void xen_bus_dmamap_sync(bus_dma_tag_t t, bus_dmamap_t map, bus_addr_t addr, bus_size_t size, int op) { if ((op == (BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE)) || (op == (BUS_DMASYNC_POSTREAD | BUS_DMASYNC_POSTWRITE))) virtio_membar_sync(); } static int xen_attach_print(void *aux, const char *name) { struct xen_attach_args *xa = aux; if (name) printf("\"%s\" at %s: %s", xa->xa_name, name, xa->xa_node); return (UNCONF); } int xen_attach_device(struct xen_softc *sc, struct xen_devlist *xdl, const char *name, const char *unit) { struct xen_attach_args xa; struct xen_device *xdv; unsigned long long res; xa.xa_dmat = &xen_bus_dma_tag; strlcpy(xa.xa_name, name, sizeof(xa.xa_name)); snprintf(xa.xa_node, sizeof(xa.xa_node), "device/%s/%s", name, unit); if (xs_getprop(sc, xa.xa_node, "backend", xa.xa_backend, sizeof(xa.xa_backend))) { DPRINTF("%s: failed to identify \"backend\" for " "\"%s\"\n", sc->sc_dev.dv_xname, xa.xa_node); return (EIO); } if (xs_getnum(sc, xa.xa_node, "backend-id", &res) || res > UINT16_MAX) { DPRINTF("%s: invalid \"backend-id\" for \"%s\"\n", sc->sc_dev.dv_xname, xa.xa_node); return (EIO); } xa.xa_domid = (uint16_t)res; xdv = malloc(sizeof(struct xen_device), M_DEVBUF, M_ZERO | M_NOWAIT); if (xdv == NULL) return (ENOMEM); strlcpy(xdv->dv_unit, unit, sizeof(xdv->dv_unit)); LIST_INSERT_HEAD(&xdl->dl_devs, xdv, dv_entry); xdv->dv_dev = config_found((struct device *)sc, &xa, xen_attach_print); return (0); } int xen_probe_devices(struct xen_softc *sc) { struct xen_devlist *xdl; struct xs_transaction xst; struct iovec *iovp1 = NULL, *iovp2 = NULL; int i, j, error, iov1_cnt = 0, iov2_cnt = 0; char path[256]; memset(&xst, 0, sizeof(xst)); xst.xst_id = 0; xst.xst_cookie = sc->sc_xs; if ((error = xs_cmd(&xst, XS_LIST, "device", &iovp1, &iov1_cnt)) != 0) return (error); for (i = 0; i < iov1_cnt; i++) { if (strcmp("suspend", (char *)iovp1[i].iov_base) == 0) continue; snprintf(path, sizeof(path), "device/%s", (char *)iovp1[i].iov_base); if ((error = xs_cmd(&xst, XS_LIST, path, &iovp2, &iov2_cnt)) != 0) goto out; if ((xdl = malloc(sizeof(struct xen_devlist), M_DEVBUF, M_ZERO | M_NOWAIT)) == NULL) { error = ENOMEM; goto out; } xdl->dl_xen = sc; strlcpy(xdl->dl_node, (const char *)iovp1[i].iov_base, XEN_MAX_NODE_LEN); for (j = 0; j < iov2_cnt; j++) { error = xen_attach_device(sc, xdl, (const char *)iovp1[i].iov_base, (const char *)iovp2[j].iov_base); if (error) { printf("%s: failed to attach \"%s/%s\"\n", sc->sc_dev.dv_xname, path, (const char *)iovp2[j].iov_base); goto out; } } /* Setup a watch for every device subtree */ if (xs_watch(sc, "device", (char *)iovp1[i].iov_base, &xdl->dl_task, xen_hotplug, xdl)) printf("%s: failed to setup hotplug watch for \"%s\"\n", sc->sc_dev.dv_xname, (char *)iovp1[i].iov_base); SLIST_INSERT_HEAD(&sc->sc_devlists, xdl, dl_entry); xs_resfree(&xst, iovp2, iov2_cnt); iovp2 = NULL; iov2_cnt = 0; } out: if (iovp2) xs_resfree(&xst, iovp2, iov2_cnt); xs_resfree(&xst, iovp1, iov1_cnt); return (error); } void xen_hotplug(void *arg) { struct xen_devlist *xdl = arg; struct xen_softc *sc = xdl->dl_xen; struct xen_device *xdv, *xvdn; struct xs_transaction xst; struct iovec *iovp = NULL; int error, i, keep, iov_cnt = 0; char path[256]; int8_t *seen; memset(&xst, 0, sizeof(xst)); xst.xst_id = 0; xst.xst_cookie = sc->sc_xs; snprintf(path, sizeof(path), "device/%s", xdl->dl_node); if ((error = xs_cmd(&xst, XS_LIST, path, &iovp, &iov_cnt)) != 0) return; seen = malloc(iov_cnt, M_TEMP, M_ZERO | M_WAITOK); /* Detect all removed and kept devices */ LIST_FOREACH_SAFE(xdv, &xdl->dl_devs, dv_entry, xvdn) { for (i = 0, keep = 0; i < iov_cnt; i++) { if (!seen[i] && !strcmp(xdv->dv_unit, (char *)iovp[i].iov_base)) { seen[i]++; keep++; break; } } if (!keep) { DPRINTF("%s: removing \"%s/%s\"\n", sc->sc_dev.dv_xname, xdl->dl_node, xdv->dv_unit); LIST_REMOVE(xdv, dv_entry); config_detach(xdv->dv_dev, 0); free(xdv, M_DEVBUF, sizeof(struct xen_device)); } } /* Attach all new devices */ for (i = 0; i < iov_cnt; i++) { if (seen[i]) continue; DPRINTF("%s: attaching \"%s/%s\"\n", sc->sc_dev.dv_xname, xdl->dl_node, (const char *)iovp[i].iov_base); error = xen_attach_device(sc, xdl, xdl->dl_node, (const char *)iovp[i].iov_base); if (error) { printf("%s: failed to attach \"%s/%s\"\n", sc->sc_dev.dv_xname, path, (const char *)iovp[i].iov_base); continue; } } free(seen, M_TEMP, iov_cnt); xs_resfree(&xst, iovp, iov_cnt); } #include #define XMI_PORT 0x10 #define XMI_MAGIC 0x49d2 #define XMI_UNPLUG_IDE 0x01 #define XMI_UNPLUG_NIC 0x02 #define XMI_UNPLUG_IDESEC 0x04 void xen_disable_emulated_devices(struct xen_softc *sc) { #if defined(__i386__) || defined(__amd64__) ushort unplug = 0; if (inw(XMI_PORT) != XMI_MAGIC) { printf("%s: failed to disable emulated devices\n", sc->sc_dev.dv_xname); return; } if (sc->sc_unplug & XEN_UNPLUG_IDE) unplug |= XMI_UNPLUG_IDE; if (sc->sc_unplug & XEN_UNPLUG_IDESEC) unplug |= XMI_UNPLUG_IDESEC; if (sc->sc_unplug & XEN_UNPLUG_NIC) unplug |= XMI_UNPLUG_NIC; if (unplug) outw(XMI_PORT, unplug); #endif /* __i386__ || __amd64__ */ } void xen_unplug_emulated(void *xsc, int what) { struct xen_softc *sc = xsc; sc->sc_unplug |= what; }