/*- * BSD LICENSE * * Copyright(c) Intel Corporation. All rights reserved. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * * Neither the name of Intel Corporation nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include "spdk/stdinc.h" #include "spdk/env.h" #include "spdk/likely.h" #include "spdk/string.h" #include "spdk/util.h" #include "spdk/memory.h" #include "spdk/barrier.h" #include "spdk/vhost.h" #include "vhost_internal.h" bool g_packed_ring_recovery = false; static struct spdk_cpuset g_vhost_core_mask; /* Path to folder where character device will be created. Can be set by user. */ static char dev_dirname[PATH_MAX] = ""; /* Thread performing all vhost management operations */ static struct spdk_thread *g_vhost_init_thread; static spdk_vhost_fini_cb g_fini_cpl_cb; /** * DPDK calls our callbacks synchronously but the work those callbacks * perform needs to be async. Luckily, all DPDK callbacks are called on * a DPDK-internal pthread, so we'll just wait on a semaphore in there. */ static sem_t g_dpdk_sem; /** Return code for the current DPDK callback */ static int g_dpdk_response; struct vhost_session_fn_ctx { /** Device pointer obtained before enqueuing the event */ struct spdk_vhost_dev *vdev; /** ID of the session to send event to. */ uint32_t vsession_id; /** User provided function to be executed on session's thread. */ spdk_vhost_session_fn cb_fn; /** * User provided function to be called on the init thread * after iterating through all sessions. */ spdk_vhost_dev_fn cpl_fn; /** Custom user context */ void *user_ctx; }; static TAILQ_HEAD(, spdk_vhost_dev) g_vhost_devices = TAILQ_HEAD_INITIALIZER( g_vhost_devices); static pthread_mutex_t g_vhost_mutex = PTHREAD_MUTEX_INITIALIZER; void *vhost_gpa_to_vva(struct spdk_vhost_session *vsession, uint64_t addr, uint64_t len) { void *vva; uint64_t newlen; newlen = len; vva = (void *)rte_vhost_va_from_guest_pa(vsession->mem, addr, &newlen); if (newlen != len) { return NULL; } return vva; } static void vhost_log_req_desc(struct spdk_vhost_session *vsession, struct spdk_vhost_virtqueue *virtqueue, uint16_t req_id) { struct vring_desc *desc, *desc_table; uint32_t desc_table_size; int rc; if (spdk_likely(!vhost_dev_has_feature(vsession, VHOST_F_LOG_ALL))) { return; } rc = vhost_vq_get_desc(vsession, virtqueue, req_id, &desc, &desc_table, &desc_table_size); if (spdk_unlikely(rc != 0)) { SPDK_ERRLOG("Can't log used ring descriptors!\n"); return; } do { if (vhost_vring_desc_is_wr(desc)) { /* To be honest, only pages realy touched should be logged, but * doing so would require tracking those changes in each backed. * Also backend most likely will touch all/most of those pages so * for lets assume we touched all pages passed to as writeable buffers. */ rte_vhost_log_write(vsession->vid, desc->addr, desc->len); } vhost_vring_desc_get_next(&desc, desc_table, desc_table_size); } while (desc); } static void vhost_log_used_vring_elem(struct spdk_vhost_session *vsession, struct spdk_vhost_virtqueue *virtqueue, uint16_t idx) { uint64_t offset, len; if (spdk_likely(!vhost_dev_has_feature(vsession, VHOST_F_LOG_ALL))) { return; } if (spdk_unlikely(virtqueue->packed.packed_ring)) { offset = idx * sizeof(struct vring_packed_desc); len = sizeof(struct vring_packed_desc); } else { offset = offsetof(struct vring_used, ring[idx]); len = sizeof(virtqueue->vring.used->ring[idx]); } rte_vhost_log_used_vring(vsession->vid, virtqueue->vring_idx, offset, len); } static void vhost_log_used_vring_idx(struct spdk_vhost_session *vsession, struct spdk_vhost_virtqueue *virtqueue) { uint64_t offset, len; uint16_t vq_idx; if (spdk_likely(!vhost_dev_has_feature(vsession, VHOST_F_LOG_ALL))) { return; } offset = offsetof(struct vring_used, idx); len = sizeof(virtqueue->vring.used->idx); vq_idx = virtqueue - vsession->virtqueue; rte_vhost_log_used_vring(vsession->vid, vq_idx, offset, len); } /* * Get available requests from avail ring. */ uint16_t vhost_vq_avail_ring_get(struct spdk_vhost_virtqueue *virtqueue, uint16_t *reqs, uint16_t reqs_len) { struct rte_vhost_vring *vring = &virtqueue->vring; struct vring_avail *avail = vring->avail; uint16_t size_mask = vring->size - 1; uint16_t last_idx = virtqueue->last_avail_idx, avail_idx = avail->idx; uint16_t count, i; int rc; uint64_t u64_value; spdk_smp_rmb(); if (virtqueue->vsession && spdk_unlikely(virtqueue->vsession->interrupt_mode)) { /* Read to clear vring's kickfd */ rc = read(vring->kickfd, &u64_value, sizeof(u64_value)); if (rc < 0) { SPDK_ERRLOG("failed to acknowledge kickfd: %s.\n", spdk_strerror(errno)); return -errno; } } count = avail_idx - last_idx; if (spdk_likely(count == 0)) { return 0; } if (spdk_unlikely(count > vring->size)) { /* TODO: the queue is unrecoverably broken and should be marked so. * For now we will fail silently and report there are no new avail entries. */ return 0; } count = spdk_min(count, reqs_len); virtqueue->last_avail_idx += count; /* Check whether there are unprocessed reqs in vq, then kick vq manually */ if (virtqueue->vsession && spdk_unlikely(virtqueue->vsession->interrupt_mode)) { /* If avail_idx is larger than virtqueue's last_avail_idx, then there is unprocessed reqs. * avail_idx should get updated here from memory, in case of race condition with guest. */ avail_idx = * (volatile uint16_t *) &avail->idx; if (avail_idx > virtqueue->last_avail_idx) { /* Write to notify vring's kickfd */ rc = write(vring->kickfd, &u64_value, sizeof(u64_value)); if (rc < 0) { SPDK_ERRLOG("failed to kick vring: %s.\n", spdk_strerror(errno)); return -errno; } } } for (i = 0; i < count; i++) { reqs[i] = vring->avail->ring[(last_idx + i) & size_mask]; } SPDK_DEBUGLOG(vhost_ring, "AVAIL: last_idx=%"PRIu16" avail_idx=%"PRIu16" count=%"PRIu16"\n", last_idx, avail_idx, count); return count; } static bool vhost_vring_desc_is_indirect(struct vring_desc *cur_desc) { return !!(cur_desc->flags & VRING_DESC_F_INDIRECT); } static bool vhost_vring_packed_desc_is_indirect(struct vring_packed_desc *cur_desc) { return (cur_desc->flags & VRING_DESC_F_INDIRECT) != 0; } static bool vhost_inflight_packed_desc_is_indirect(spdk_vhost_inflight_desc *cur_desc) { return (cur_desc->flags & VRING_DESC_F_INDIRECT) != 0; } int vhost_vq_get_desc(struct spdk_vhost_session *vsession, struct spdk_vhost_virtqueue *virtqueue, uint16_t req_idx, struct vring_desc **desc, struct vring_desc **desc_table, uint32_t *desc_table_size) { if (spdk_unlikely(req_idx >= virtqueue->vring.size)) { return -1; } *desc = &virtqueue->vring.desc[req_idx]; if (vhost_vring_desc_is_indirect(*desc)) { *desc_table_size = (*desc)->len / sizeof(**desc); *desc_table = vhost_gpa_to_vva(vsession, (*desc)->addr, sizeof(**desc) * *desc_table_size); *desc = *desc_table; if (*desc == NULL) { return -1; } return 0; } *desc_table = virtqueue->vring.desc; *desc_table_size = virtqueue->vring.size; return 0; } static bool vhost_packed_desc_indirect_to_desc_table(struct spdk_vhost_session *vsession, uint64_t addr, uint32_t len, struct vring_packed_desc **desc_table, uint32_t *desc_table_size) { *desc_table_size = len / sizeof(struct vring_packed_desc); *desc_table = vhost_gpa_to_vva(vsession, addr, len); if (spdk_unlikely(*desc_table == NULL)) { return false; } return true; } int vhost_vq_get_desc_packed(struct spdk_vhost_session *vsession, struct spdk_vhost_virtqueue *virtqueue, uint16_t req_idx, struct vring_packed_desc **desc, struct vring_packed_desc **desc_table, uint32_t *desc_table_size) { *desc = &virtqueue->vring.desc_packed[req_idx]; /* In packed ring when the desc is non-indirect we get next desc * by judging (desc->flag & VRING_DESC_F_NEXT) != 0. When the desc * is indirect we get next desc by idx and desc_table_size. It's * different from split ring. */ if (vhost_vring_packed_desc_is_indirect(*desc)) { if (!vhost_packed_desc_indirect_to_desc_table(vsession, (*desc)->addr, (*desc)->len, desc_table, desc_table_size)) { return -1; } *desc = *desc_table; } else { *desc_table = NULL; *desc_table_size = 0; } return 0; } int vhost_inflight_queue_get_desc(struct spdk_vhost_session *vsession, spdk_vhost_inflight_desc *desc_array, uint16_t req_idx, spdk_vhost_inflight_desc **desc, struct vring_packed_desc **desc_table, uint32_t *desc_table_size) { *desc = &desc_array[req_idx]; if (vhost_inflight_packed_desc_is_indirect(*desc)) { if (!vhost_packed_desc_indirect_to_desc_table(vsession, (*desc)->addr, (*desc)->len, desc_table, desc_table_size)) { return -1; } /* This desc is the inflight desc not the packed desc. * When set the F_INDIRECT the table entry should be the packed desc * so set the inflight desc NULL. */ *desc = NULL; } else { /* When not set the F_INDIRECT means there is no packed desc table */ *desc_table = NULL; *desc_table_size = 0; } return 0; } int vhost_vq_used_signal(struct spdk_vhost_session *vsession, struct spdk_vhost_virtqueue *virtqueue) { if (virtqueue->used_req_cnt == 0) { return 0; } virtqueue->req_cnt += virtqueue->used_req_cnt; virtqueue->used_req_cnt = 0; SPDK_DEBUGLOG(vhost_ring, "Queue %td - USED RING: sending IRQ: last used %"PRIu16"\n", virtqueue - vsession->virtqueue, virtqueue->last_used_idx); if (rte_vhost_vring_call(vsession->vid, virtqueue->vring_idx) == 0) { /* interrupt signalled */ return 1; } else { /* interrupt not signalled */ return 0; } } static void session_vq_io_stats_update(struct spdk_vhost_session *vsession, struct spdk_vhost_virtqueue *virtqueue, uint64_t now) { uint32_t irq_delay_base = vsession->coalescing_delay_time_base; uint32_t io_threshold = vsession->coalescing_io_rate_threshold; int32_t irq_delay; uint32_t req_cnt; req_cnt = virtqueue->req_cnt + virtqueue->used_req_cnt; if (req_cnt <= io_threshold) { return; } irq_delay = (irq_delay_base * (req_cnt - io_threshold)) / io_threshold; virtqueue->irq_delay_time = (uint32_t) spdk_max(0, irq_delay); virtqueue->req_cnt = 0; virtqueue->next_event_time = now; } static void check_session_vq_io_stats(struct spdk_vhost_session *vsession, struct spdk_vhost_virtqueue *virtqueue, uint64_t now) { if (now < vsession->next_stats_check_time) { return; } vsession->next_stats_check_time = now + vsession->stats_check_interval; session_vq_io_stats_update(vsession, virtqueue, now); } static inline bool vhost_vq_event_is_suppressed(struct spdk_vhost_virtqueue *vq) { if (spdk_unlikely(vq->packed.packed_ring)) { if (vq->vring.driver_event->flags & VRING_PACKED_EVENT_FLAG_DISABLE) { return true; } } else { if (vq->vring.avail->flags & VRING_AVAIL_F_NO_INTERRUPT) { return true; } } return false; } void vhost_session_vq_used_signal(struct spdk_vhost_virtqueue *virtqueue) { struct spdk_vhost_session *vsession = virtqueue->vsession; uint64_t now; if (vsession->coalescing_delay_time_base == 0) { if (virtqueue->vring.desc == NULL) { return; } if (vhost_vq_event_is_suppressed(virtqueue)) { return; } vhost_vq_used_signal(vsession, virtqueue); } else { now = spdk_get_ticks(); check_session_vq_io_stats(vsession, virtqueue, now); /* No need for event right now */ if (now < virtqueue->next_event_time) { return; } if (vhost_vq_event_is_suppressed(virtqueue)) { return; } if (!vhost_vq_used_signal(vsession, virtqueue)) { return; } /* Syscall is quite long so update time */ now = spdk_get_ticks(); virtqueue->next_event_time = now + virtqueue->irq_delay_time; } } void vhost_session_used_signal(struct spdk_vhost_session *vsession) { struct spdk_vhost_virtqueue *virtqueue; uint16_t q_idx; for (q_idx = 0; q_idx < vsession->max_queues; q_idx++) { virtqueue = &vsession->virtqueue[q_idx]; vhost_session_vq_used_signal(virtqueue); } } static int vhost_session_set_coalescing(struct spdk_vhost_dev *vdev, struct spdk_vhost_session *vsession, void *ctx) { vsession->coalescing_delay_time_base = vdev->coalescing_delay_us * spdk_get_ticks_hz() / 1000000ULL; vsession->coalescing_io_rate_threshold = vdev->coalescing_iops_threshold * SPDK_VHOST_STATS_CHECK_INTERVAL_MS / 1000U; return 0; } static int vhost_dev_set_coalescing(struct spdk_vhost_dev *vdev, uint32_t delay_base_us, uint32_t iops_threshold) { uint64_t delay_time_base = delay_base_us * spdk_get_ticks_hz() / 1000000ULL; uint32_t io_rate = iops_threshold * SPDK_VHOST_STATS_CHECK_INTERVAL_MS / 1000U; if (delay_time_base >= UINT32_MAX) { SPDK_ERRLOG("Delay time of %"PRIu32" is to big\n", delay_base_us); return -EINVAL; } else if (io_rate == 0) { SPDK_ERRLOG("IOPS rate of %"PRIu32" is too low. Min is %u\n", io_rate, 1000U / SPDK_VHOST_STATS_CHECK_INTERVAL_MS); return -EINVAL; } vdev->coalescing_delay_us = delay_base_us; vdev->coalescing_iops_threshold = iops_threshold; return 0; } int spdk_vhost_set_coalescing(struct spdk_vhost_dev *vdev, uint32_t delay_base_us, uint32_t iops_threshold) { int rc; rc = vhost_dev_set_coalescing(vdev, delay_base_us, iops_threshold); if (rc != 0) { return rc; } vhost_dev_foreach_session(vdev, vhost_session_set_coalescing, NULL, NULL); return 0; } void spdk_vhost_get_coalescing(struct spdk_vhost_dev *vdev, uint32_t *delay_base_us, uint32_t *iops_threshold) { if (delay_base_us) { *delay_base_us = vdev->coalescing_delay_us; } if (iops_threshold) { *iops_threshold = vdev->coalescing_iops_threshold; } } /* * Enqueue id and len to used ring. */ void vhost_vq_used_ring_enqueue(struct spdk_vhost_session *vsession, struct spdk_vhost_virtqueue *virtqueue, uint16_t id, uint32_t len) { struct rte_vhost_vring *vring = &virtqueue->vring; struct vring_used *used = vring->used; uint16_t last_idx = virtqueue->last_used_idx & (vring->size - 1); uint16_t vq_idx = virtqueue->vring_idx; SPDK_DEBUGLOG(vhost_ring, "Queue %td - USED RING: last_idx=%"PRIu16" req id=%"PRIu16" len=%"PRIu32"\n", virtqueue - vsession->virtqueue, virtqueue->last_used_idx, id, len); vhost_log_req_desc(vsession, virtqueue, id); virtqueue->last_used_idx++; used->ring[last_idx].id = id; used->ring[last_idx].len = len; /* Ensure the used ring is updated before we log it or increment used->idx. */ spdk_smp_wmb(); rte_vhost_set_last_inflight_io_split(vsession->vid, vq_idx, id); vhost_log_used_vring_elem(vsession, virtqueue, last_idx); * (volatile uint16_t *) &used->idx = virtqueue->last_used_idx; vhost_log_used_vring_idx(vsession, virtqueue); rte_vhost_clr_inflight_desc_split(vsession->vid, vq_idx, virtqueue->last_used_idx, id); virtqueue->used_req_cnt++; if (vsession->interrupt_mode) { if (virtqueue->vring.desc == NULL || vhost_vq_event_is_suppressed(virtqueue)) { return; } vhost_vq_used_signal(vsession, virtqueue); } } void vhost_vq_packed_ring_enqueue(struct spdk_vhost_session *vsession, struct spdk_vhost_virtqueue *virtqueue, uint16_t num_descs, uint16_t buffer_id, uint32_t length, uint16_t inflight_head) { struct vring_packed_desc *desc = &virtqueue->vring.desc_packed[virtqueue->last_used_idx]; bool used, avail; SPDK_DEBUGLOG(vhost_ring, "Queue %td - RING: buffer_id=%"PRIu16"\n", virtqueue - vsession->virtqueue, buffer_id); /* When the descriptor is used, two flags in descriptor * avail flag and used flag are set to equal * and used flag value == used_wrap_counter. */ used = !!(desc->flags & VRING_DESC_F_USED); avail = !!(desc->flags & VRING_DESC_F_AVAIL); if (spdk_unlikely(used == virtqueue->packed.used_phase && used == avail)) { SPDK_ERRLOG("descriptor has been used before\n"); return; } /* In used desc addr is unused and len specifies the buffer length * that has been written to by the device. */ desc->addr = 0; desc->len = length; /* This bit specifies whether any data has been written by the device */ if (length != 0) { desc->flags |= VRING_DESC_F_WRITE; } /* Buffer ID is included in the last descriptor in the list. * The driver needs to keep track of the size of the list corresponding * to each buffer ID. */ desc->id = buffer_id; /* A device MUST NOT make the descriptor used before buffer_id is * written to the descriptor. */ spdk_smp_wmb(); rte_vhost_set_last_inflight_io_packed(vsession->vid, virtqueue->vring_idx, inflight_head); /* To mark a desc as used, the device sets the F_USED bit in flags to match * the internal Device ring wrap counter. It also sets the F_AVAIL bit to * match the same value. */ if (virtqueue->packed.used_phase) { desc->flags |= VRING_DESC_F_AVAIL_USED; } else { desc->flags &= ~VRING_DESC_F_AVAIL_USED; } rte_vhost_clr_inflight_desc_packed(vsession->vid, virtqueue->vring_idx, inflight_head); vhost_log_used_vring_elem(vsession, virtqueue, virtqueue->last_used_idx); virtqueue->last_used_idx += num_descs; if (virtqueue->last_used_idx >= virtqueue->vring.size) { virtqueue->last_used_idx -= virtqueue->vring.size; virtqueue->packed.used_phase = !virtqueue->packed.used_phase; } virtqueue->used_req_cnt++; } bool vhost_vq_packed_ring_is_avail(struct spdk_vhost_virtqueue *virtqueue) { uint16_t flags = virtqueue->vring.desc_packed[virtqueue->last_avail_idx].flags; /* To mark a desc as available, the driver sets the F_AVAIL bit in flags * to match the internal avail wrap counter. It also sets the F_USED bit to * match the inverse value but it's not mandatory. */ return (!!(flags & VRING_DESC_F_AVAIL) == virtqueue->packed.avail_phase); } bool vhost_vring_packed_desc_is_wr(struct vring_packed_desc *cur_desc) { return (cur_desc->flags & VRING_DESC_F_WRITE) != 0; } bool vhost_vring_inflight_desc_is_wr(spdk_vhost_inflight_desc *cur_desc) { return (cur_desc->flags & VRING_DESC_F_WRITE) != 0; } int vhost_vring_packed_desc_get_next(struct vring_packed_desc **desc, uint16_t *req_idx, struct spdk_vhost_virtqueue *vq, struct vring_packed_desc *desc_table, uint32_t desc_table_size) { if (desc_table != NULL) { /* When the desc_table isn't NULL means it's indirect and we get the next * desc by req_idx and desc_table_size. The return value is NULL means * we reach the last desc of this request. */ (*req_idx)++; if (*req_idx < desc_table_size) { *desc = &desc_table[*req_idx]; } else { *desc = NULL; } } else { /* When the desc_table is NULL means it's non-indirect and we get the next * desc by req_idx and F_NEXT in flags. The return value is NULL means * we reach the last desc of this request. When return new desc * we update the req_idx too. */ if (((*desc)->flags & VRING_DESC_F_NEXT) == 0) { *desc = NULL; return 0; } *req_idx = (*req_idx + 1) % vq->vring.size; *desc = &vq->vring.desc_packed[*req_idx]; } return 0; } static int vhost_vring_desc_payload_to_iov(struct spdk_vhost_session *vsession, struct iovec *iov, uint16_t *iov_index, uintptr_t payload, uint64_t remaining) { uintptr_t vva; uint64_t len; do { if (*iov_index >= SPDK_VHOST_IOVS_MAX) { SPDK_ERRLOG("SPDK_VHOST_IOVS_MAX(%d) reached\n", SPDK_VHOST_IOVS_MAX); return -1; } len = remaining; vva = (uintptr_t)rte_vhost_va_from_guest_pa(vsession->mem, payload, &len); if (vva == 0 || len == 0) { SPDK_ERRLOG("gpa_to_vva(%p) == NULL\n", (void *)payload); return -1; } iov[*iov_index].iov_base = (void *)vva; iov[*iov_index].iov_len = len; remaining -= len; payload += len; (*iov_index)++; } while (remaining); return 0; } int vhost_vring_packed_desc_to_iov(struct spdk_vhost_session *vsession, struct iovec *iov, uint16_t *iov_index, const struct vring_packed_desc *desc) { return vhost_vring_desc_payload_to_iov(vsession, iov, iov_index, desc->addr, desc->len); } int vhost_vring_inflight_desc_to_iov(struct spdk_vhost_session *vsession, struct iovec *iov, uint16_t *iov_index, const spdk_vhost_inflight_desc *desc) { return vhost_vring_desc_payload_to_iov(vsession, iov, iov_index, desc->addr, desc->len); } /* 1, Traverse the desc chain to get the buffer_id and return buffer_id as task_idx. * 2, Update the vq->last_avail_idx to point next available desc chain. * 3, Update the avail_wrap_counter if last_avail_idx overturn. */ uint16_t vhost_vring_packed_desc_get_buffer_id(struct spdk_vhost_virtqueue *vq, uint16_t req_idx, uint16_t *num_descs) { struct vring_packed_desc *desc; uint16_t desc_head = req_idx; *num_descs = 1; desc = &vq->vring.desc_packed[req_idx]; if (!vhost_vring_packed_desc_is_indirect(desc)) { while ((desc->flags & VRING_DESC_F_NEXT) != 0) { req_idx = (req_idx + 1) % vq->vring.size; desc = &vq->vring.desc_packed[req_idx]; (*num_descs)++; } } /* Queue Size doesn't have to be a power of 2 * Device maintains last_avail_idx so we can make sure * the value is valid(0 ~ vring.size - 1) */ vq->last_avail_idx = (req_idx + 1) % vq->vring.size; if (vq->last_avail_idx < desc_head) { vq->packed.avail_phase = !vq->packed.avail_phase; } return desc->id; } int vhost_vring_desc_get_next(struct vring_desc **desc, struct vring_desc *desc_table, uint32_t desc_table_size) { struct vring_desc *old_desc = *desc; uint16_t next_idx; if ((old_desc->flags & VRING_DESC_F_NEXT) == 0) { *desc = NULL; return 0; } next_idx = old_desc->next; if (spdk_unlikely(next_idx >= desc_table_size)) { *desc = NULL; return -1; } *desc = &desc_table[next_idx]; return 0; } int vhost_vring_desc_to_iov(struct spdk_vhost_session *vsession, struct iovec *iov, uint16_t *iov_index, const struct vring_desc *desc) { return vhost_vring_desc_payload_to_iov(vsession, iov, iov_index, desc->addr, desc->len); } static struct spdk_vhost_session * vhost_session_find_by_id(struct spdk_vhost_dev *vdev, unsigned id) { struct spdk_vhost_session *vsession; TAILQ_FOREACH(vsession, &vdev->vsessions, tailq) { if (vsession->id == id) { return vsession; } } return NULL; } struct spdk_vhost_session * vhost_session_find_by_vid(int vid) { struct spdk_vhost_dev *vdev; struct spdk_vhost_session *vsession; TAILQ_FOREACH(vdev, &g_vhost_devices, tailq) { TAILQ_FOREACH(vsession, &vdev->vsessions, tailq) { if (vsession->vid == vid) { return vsession; } } } return NULL; } struct spdk_vhost_dev * spdk_vhost_dev_next(struct spdk_vhost_dev *vdev) { if (vdev == NULL) { return TAILQ_FIRST(&g_vhost_devices); } return TAILQ_NEXT(vdev, tailq); } struct spdk_vhost_dev * spdk_vhost_dev_find(const char *ctrlr_name) { struct spdk_vhost_dev *vdev; size_t dev_dirname_len = strlen(dev_dirname); if (strncmp(ctrlr_name, dev_dirname, dev_dirname_len) == 0) { ctrlr_name += dev_dirname_len; } TAILQ_FOREACH(vdev, &g_vhost_devices, tailq) { if (strcmp(vdev->name, ctrlr_name) == 0) { return vdev; } } return NULL; } static int vhost_parse_core_mask(const char *mask, struct spdk_cpuset *cpumask) { int rc; struct spdk_cpuset negative_vhost_mask; if (cpumask == NULL) { return -1; } if (mask == NULL) { spdk_cpuset_copy(cpumask, &g_vhost_core_mask); return 0; } rc = spdk_cpuset_parse(cpumask, mask); if (rc < 0) { SPDK_ERRLOG("invalid cpumask %s\n", mask); return -1; } spdk_cpuset_copy(&negative_vhost_mask, &g_vhost_core_mask); spdk_cpuset_negate(&negative_vhost_mask); spdk_cpuset_and(&negative_vhost_mask, cpumask); if (spdk_cpuset_count(&negative_vhost_mask) != 0) { SPDK_ERRLOG("one of selected cpu is outside of core mask(=%s)\n", spdk_cpuset_fmt(&g_vhost_core_mask)); return -1; } spdk_cpuset_and(cpumask, &g_vhost_core_mask); if (spdk_cpuset_count(cpumask) == 0) { SPDK_ERRLOG("no cpu is selected among core mask(=%s)\n", spdk_cpuset_fmt(&g_vhost_core_mask)); return -1; } return 0; } static void vhost_dev_thread_exit(void *arg1) { spdk_thread_exit(spdk_get_thread()); } int vhost_dev_register(struct spdk_vhost_dev *vdev, const char *name, const char *mask_str, const struct spdk_vhost_dev_backend *backend) { char path[PATH_MAX]; struct spdk_cpuset cpumask = {}; int rc; assert(vdev); if (name == NULL) { SPDK_ERRLOG("Can't register controller with no name\n"); return -EINVAL; } if (vhost_parse_core_mask(mask_str, &cpumask) != 0) { SPDK_ERRLOG("cpumask %s is invalid (core mask is 0x%s)\n", mask_str, spdk_cpuset_fmt(&g_vhost_core_mask)); return -EINVAL; } if (spdk_vhost_dev_find(name)) { SPDK_ERRLOG("vhost controller %s already exists.\n", name); return -EEXIST; } if (snprintf(path, sizeof(path), "%s%s", dev_dirname, name) >= (int)sizeof(path)) { SPDK_ERRLOG("Resulting socket path for controller %s is too long: %s%s\n", name, dev_dirname, name); return -EINVAL; } vdev->name = strdup(name); vdev->path = strdup(path); if (vdev->name == NULL || vdev->path == NULL) { rc = -EIO; goto out; } vdev->thread = spdk_thread_create(vdev->name, &cpumask); if (vdev->thread == NULL) { SPDK_ERRLOG("Failed to create thread for vhost controller %s.\n", name); rc = -EIO; goto out; } vdev->registered = true; vdev->backend = backend; TAILQ_INIT(&vdev->vsessions); vhost_dev_set_coalescing(vdev, SPDK_VHOST_COALESCING_DELAY_BASE_US, SPDK_VHOST_VQ_IOPS_COALESCING_THRESHOLD); if (vhost_register_unix_socket(path, name, vdev->virtio_features, vdev->disabled_features, vdev->protocol_features)) { spdk_thread_send_msg(vdev->thread, vhost_dev_thread_exit, NULL); rc = -EIO; goto out; } TAILQ_INSERT_TAIL(&g_vhost_devices, vdev, tailq); SPDK_INFOLOG(vhost, "Controller %s: new controller added\n", vdev->name); return 0; out: free(vdev->name); free(vdev->path); return rc; } int vhost_dev_unregister(struct spdk_vhost_dev *vdev) { if (!TAILQ_EMPTY(&vdev->vsessions)) { SPDK_ERRLOG("Controller %s has still valid connection.\n", vdev->name); return -EBUSY; } if (vdev->registered && vhost_driver_unregister(vdev->path) != 0) { SPDK_ERRLOG("Could not unregister controller %s with vhost library\n" "Check if domain socket %s still exists\n", vdev->name, vdev->path); return -EIO; } SPDK_INFOLOG(vhost, "Controller %s: removed\n", vdev->name); spdk_thread_send_msg(vdev->thread, vhost_dev_thread_exit, NULL); free(vdev->name); free(vdev->path); TAILQ_REMOVE(&g_vhost_devices, vdev, tailq); return 0; } const char * spdk_vhost_dev_get_name(struct spdk_vhost_dev *vdev) { assert(vdev != NULL); return vdev->name; } const struct spdk_cpuset * spdk_vhost_dev_get_cpumask(struct spdk_vhost_dev *vdev) { assert(vdev != NULL); return spdk_thread_get_cpumask(vdev->thread); } static void wait_for_semaphore(int timeout_sec, const char *errmsg) { struct timespec timeout; int rc; clock_gettime(CLOCK_REALTIME, &timeout); timeout.tv_sec += timeout_sec; rc = sem_timedwait(&g_dpdk_sem, &timeout); if (rc != 0) { SPDK_ERRLOG("Timeout waiting for event: %s.\n", errmsg); sem_wait(&g_dpdk_sem); } } static void vhost_session_cb_done(int rc) { g_dpdk_response = rc; sem_post(&g_dpdk_sem); } void vhost_session_start_done(struct spdk_vhost_session *vsession, int response) { if (response == 0) { vsession->started = true; assert(vsession->vdev->active_session_num < UINT32_MAX); vsession->vdev->active_session_num++; } vhost_session_cb_done(response); } void vhost_session_stop_done(struct spdk_vhost_session *vsession, int response) { if (response == 0) { vsession->started = false; assert(vsession->vdev->active_session_num > 0); vsession->vdev->active_session_num--; } vhost_session_cb_done(response); } static void vhost_event_cb(void *arg1) { struct vhost_session_fn_ctx *ctx = arg1; struct spdk_vhost_session *vsession; if (pthread_mutex_trylock(&g_vhost_mutex) != 0) { spdk_thread_send_msg(spdk_get_thread(), vhost_event_cb, arg1); return; } vsession = vhost_session_find_by_id(ctx->vdev, ctx->vsession_id); ctx->cb_fn(ctx->vdev, vsession, NULL); pthread_mutex_unlock(&g_vhost_mutex); } int vhost_session_send_event(struct spdk_vhost_session *vsession, spdk_vhost_session_fn cb_fn, unsigned timeout_sec, const char *errmsg) { struct vhost_session_fn_ctx ev_ctx = {0}; struct spdk_vhost_dev *vdev = vsession->vdev; ev_ctx.vdev = vdev; ev_ctx.vsession_id = vsession->id; ev_ctx.cb_fn = cb_fn; spdk_thread_send_msg(vdev->thread, vhost_event_cb, &ev_ctx); pthread_mutex_unlock(&g_vhost_mutex); wait_for_semaphore(timeout_sec, errmsg); pthread_mutex_lock(&g_vhost_mutex); return g_dpdk_response; } static void foreach_session_finish_cb(void *arg1) { struct vhost_session_fn_ctx *ev_ctx = arg1; struct spdk_vhost_dev *vdev = ev_ctx->vdev; if (pthread_mutex_trylock(&g_vhost_mutex) != 0) { spdk_thread_send_msg(spdk_get_thread(), foreach_session_finish_cb, arg1); return; } assert(vdev->pending_async_op_num > 0); vdev->pending_async_op_num--; if (ev_ctx->cpl_fn != NULL) { ev_ctx->cpl_fn(vdev, ev_ctx->user_ctx); } pthread_mutex_unlock(&g_vhost_mutex); free(ev_ctx); } static void foreach_session(void *arg1) { struct vhost_session_fn_ctx *ev_ctx = arg1; struct spdk_vhost_session *vsession; struct spdk_vhost_dev *vdev = ev_ctx->vdev; int rc; if (pthread_mutex_trylock(&g_vhost_mutex) != 0) { spdk_thread_send_msg(spdk_get_thread(), foreach_session, arg1); return; } TAILQ_FOREACH(vsession, &vdev->vsessions, tailq) { if (vsession->initialized) { rc = ev_ctx->cb_fn(vdev, vsession, ev_ctx->user_ctx); if (rc < 0) { goto out; } } } out: pthread_mutex_unlock(&g_vhost_mutex); spdk_thread_send_msg(g_vhost_init_thread, foreach_session_finish_cb, arg1); } void vhost_dev_foreach_session(struct spdk_vhost_dev *vdev, spdk_vhost_session_fn fn, spdk_vhost_dev_fn cpl_fn, void *arg) { struct vhost_session_fn_ctx *ev_ctx; ev_ctx = calloc(1, sizeof(*ev_ctx)); if (ev_ctx == NULL) { SPDK_ERRLOG("Failed to alloc vhost event.\n"); assert(false); return; } ev_ctx->vdev = vdev; ev_ctx->cb_fn = fn; ev_ctx->cpl_fn = cpl_fn; ev_ctx->user_ctx = arg; assert(vdev->pending_async_op_num < UINT32_MAX); vdev->pending_async_op_num++; spdk_thread_send_msg(vdev->thread, foreach_session, ev_ctx); } static int _stop_session(struct spdk_vhost_session *vsession) { struct spdk_vhost_dev *vdev = vsession->vdev; struct spdk_vhost_virtqueue *q; int rc; uint16_t i; rc = vdev->backend->stop_session(vsession); if (rc != 0) { SPDK_ERRLOG("Couldn't stop device with vid %d.\n", vsession->vid); pthread_mutex_unlock(&g_vhost_mutex); return rc; } for (i = 0; i < vsession->max_queues; i++) { q = &vsession->virtqueue[i]; /* vring.desc and vring.desc_packed are in a union struct * so q->vring.desc can replace q->vring.desc_packed. */ if (q->vring.desc == NULL) { continue; } /* Packed virtqueues support up to 2^15 entries each * so left one bit can be used as wrap counter. */ if (q->packed.packed_ring) { q->last_avail_idx = q->last_avail_idx | ((uint16_t)q->packed.avail_phase << 15); q->last_used_idx = q->last_used_idx | ((uint16_t)q->packed.used_phase << 15); } rte_vhost_set_vring_base(vsession->vid, i, q->last_avail_idx, q->last_used_idx); } vhost_session_mem_unregister(vsession->mem); free(vsession->mem); return 0; } int vhost_stop_device_cb(int vid) { struct spdk_vhost_session *vsession; int rc; pthread_mutex_lock(&g_vhost_mutex); vsession = vhost_session_find_by_vid(vid); if (vsession == NULL) { SPDK_ERRLOG("Couldn't find session with vid %d.\n", vid); pthread_mutex_unlock(&g_vhost_mutex); return -EINVAL; } if (!vsession->started) { /* already stopped, nothing to do */ pthread_mutex_unlock(&g_vhost_mutex); return -EALREADY; } rc = _stop_session(vsession); pthread_mutex_unlock(&g_vhost_mutex); return rc; } int vhost_start_device_cb(int vid) { struct spdk_vhost_dev *vdev; struct spdk_vhost_session *vsession; int rc = -1; uint16_t i; bool packed_ring; pthread_mutex_lock(&g_vhost_mutex); vsession = vhost_session_find_by_vid(vid); if (vsession == NULL) { SPDK_ERRLOG("Couldn't find session with vid %d.\n", vid); goto out; } if (spdk_interrupt_mode_is_enabled()) { vsession->interrupt_mode = true; } vdev = vsession->vdev; if (vsession->started) { /* already started, nothing to do */ rc = 0; goto out; } if (vhost_get_negotiated_features(vid, &vsession->negotiated_features) != 0) { SPDK_ERRLOG("vhost device %d: Failed to get negotiated driver features\n", vid); goto out; } packed_ring = ((vsession->negotiated_features & (1ULL << VIRTIO_F_RING_PACKED)) != 0); vsession->max_queues = 0; memset(vsession->virtqueue, 0, sizeof(vsession->virtqueue)); for (i = 0; i < SPDK_VHOST_MAX_VQUEUES; i++) { struct spdk_vhost_virtqueue *q = &vsession->virtqueue[i]; q->vsession = vsession; q->vring_idx = -1; if (rte_vhost_get_vhost_vring(vid, i, &q->vring)) { continue; } q->vring_idx = i; rte_vhost_get_vhost_ring_inflight(vid, i, &q->vring_inflight); /* vring.desc and vring.desc_packed are in a union struct * so q->vring.desc can replace q->vring.desc_packed. */ if (q->vring.desc == NULL || q->vring.size == 0) { continue; } if (rte_vhost_get_vring_base(vsession->vid, i, &q->last_avail_idx, &q->last_used_idx)) { q->vring.desc = NULL; continue; } if (packed_ring) { /* Use the inflight mem to restore the last_avail_idx and last_used_idx. * When the vring format is packed, there is no used_idx in the * used ring, so VM can't resend the used_idx to VHOST when reconnect. * QEMU version 5.2.0 supports the packed inflight before that it only * supports split ring inflight because it doesn't send negotiated features * before get inflight fd. Users can use RPC to enable this function. */ if (spdk_unlikely(g_packed_ring_recovery)) { rte_vhost_get_vring_base_from_inflight(vsession->vid, i, &q->last_avail_idx, &q->last_used_idx); } /* Packed virtqueues support up to 2^15 entries each * so left one bit can be used as wrap counter. */ q->packed.avail_phase = q->last_avail_idx >> 15; q->last_avail_idx = q->last_avail_idx & 0x7FFF; q->packed.used_phase = q->last_used_idx >> 15; q->last_used_idx = q->last_used_idx & 0x7FFF; if (!vsession->interrupt_mode) { /* Disable I/O submission notifications, we'll be polling. */ q->vring.device_event->flags = VRING_PACKED_EVENT_FLAG_DISABLE; } } else { if (!vsession->interrupt_mode) { /* Disable I/O submission notifications, we'll be polling. */ q->vring.used->flags = VRING_USED_F_NO_NOTIFY; } } q->packed.packed_ring = packed_ring; vsession->max_queues = i + 1; } if (vhost_get_mem_table(vid, &vsession->mem) != 0) { SPDK_ERRLOG("vhost device %d: Failed to get guest memory table\n", vid); goto out; } /* * Not sure right now but this look like some kind of QEMU bug and guest IO * might be frozed without kicking all queues after live-migration. This look like * the previous vhost instance failed to effectively deliver all interrupts before * the GET_VRING_BASE message. This shouldn't harm guest since spurious interrupts * should be ignored by guest virtio driver. * * Tested on QEMU 2.10.91 and 2.11.50. */ for (i = 0; i < vsession->max_queues; i++) { struct spdk_vhost_virtqueue *q = &vsession->virtqueue[i]; /* vring.desc and vring.desc_packed are in a union struct * so q->vring.desc can replace q->vring.desc_packed. */ if (q->vring.desc != NULL && q->vring.size > 0) { rte_vhost_vring_call(vsession->vid, q->vring_idx); } } vhost_session_set_coalescing(vdev, vsession, NULL); vhost_session_mem_register(vsession->mem); vsession->initialized = true; rc = vdev->backend->start_session(vsession); if (rc != 0) { vhost_session_mem_unregister(vsession->mem); free(vsession->mem); goto out; } out: pthread_mutex_unlock(&g_vhost_mutex); return rc; } int spdk_vhost_set_socket_path(const char *basename) { int ret; if (basename && strlen(basename) > 0) { ret = snprintf(dev_dirname, sizeof(dev_dirname) - 2, "%s", basename); if (ret <= 0) { return -EINVAL; } if ((size_t)ret >= sizeof(dev_dirname) - 2) { SPDK_ERRLOG("Char dev dir path length %d is too long\n", ret); return -EINVAL; } if (dev_dirname[ret - 1] != '/') { dev_dirname[ret] = '/'; dev_dirname[ret + 1] = '\0'; } } return 0; } void vhost_dump_info_json(struct spdk_vhost_dev *vdev, struct spdk_json_write_ctx *w) { assert(vdev->backend->dump_info_json != NULL); vdev->backend->dump_info_json(vdev, w); } int spdk_vhost_dev_remove(struct spdk_vhost_dev *vdev) { if (vdev->pending_async_op_num) { return -EBUSY; } return vdev->backend->remove_device(vdev); } int vhost_new_connection_cb(int vid, const char *ifname) { struct spdk_vhost_dev *vdev; struct spdk_vhost_session *vsession; pthread_mutex_lock(&g_vhost_mutex); vdev = spdk_vhost_dev_find(ifname); if (vdev == NULL) { SPDK_ERRLOG("Couldn't find device with vid %d to create connection for.\n", vid); pthread_mutex_unlock(&g_vhost_mutex); return -1; } /* We expect sessions inside vdev->vsessions to be sorted in ascending * order in regard of vsession->id. For now we always set id = vsessions_cnt++ * and append each session to the very end of the vsessions list. * This is required for spdk_vhost_dev_foreach_session() to work. */ if (vdev->vsessions_num == UINT_MAX) { assert(false); return -EINVAL; } if (posix_memalign((void **)&vsession, SPDK_CACHE_LINE_SIZE, sizeof(*vsession) + vdev->backend->session_ctx_size)) { SPDK_ERRLOG("vsession alloc failed\n"); pthread_mutex_unlock(&g_vhost_mutex); return -1; } memset(vsession, 0, sizeof(*vsession) + vdev->backend->session_ctx_size); vsession->vdev = vdev; vsession->vid = vid; vsession->id = vdev->vsessions_num++; vsession->name = spdk_sprintf_alloc("%ss%u", vdev->name, vsession->vid); if (vsession->name == NULL) { SPDK_ERRLOG("vsession alloc failed\n"); pthread_mutex_unlock(&g_vhost_mutex); free(vsession); return -1; } vsession->started = false; vsession->initialized = false; vsession->next_stats_check_time = 0; vsession->stats_check_interval = SPDK_VHOST_STATS_CHECK_INTERVAL_MS * spdk_get_ticks_hz() / 1000UL; TAILQ_INSERT_TAIL(&vdev->vsessions, vsession, tailq); vhost_session_install_rte_compat_hooks(vsession); pthread_mutex_unlock(&g_vhost_mutex); return 0; } int vhost_destroy_connection_cb(int vid) { struct spdk_vhost_session *vsession; int rc = 0; pthread_mutex_lock(&g_vhost_mutex); vsession = vhost_session_find_by_vid(vid); if (vsession == NULL) { SPDK_ERRLOG("Couldn't find session with vid %d.\n", vid); pthread_mutex_unlock(&g_vhost_mutex); return -EINVAL; } if (vsession->started) { rc = _stop_session(vsession); } TAILQ_REMOVE(&vsession->vdev->vsessions, vsession, tailq); free(vsession->name); free(vsession); pthread_mutex_unlock(&g_vhost_mutex); return rc; } void spdk_vhost_lock(void) { pthread_mutex_lock(&g_vhost_mutex); } int spdk_vhost_trylock(void) { return -pthread_mutex_trylock(&g_vhost_mutex); } void spdk_vhost_unlock(void) { pthread_mutex_unlock(&g_vhost_mutex); } void spdk_vhost_init(spdk_vhost_init_cb init_cb) { size_t len; uint32_t i; int ret = 0; g_vhost_init_thread = spdk_get_thread(); assert(g_vhost_init_thread != NULL); if (dev_dirname[0] == '\0') { if (getcwd(dev_dirname, sizeof(dev_dirname) - 1) == NULL) { SPDK_ERRLOG("getcwd failed (%d): %s\n", errno, spdk_strerror(errno)); ret = -1; goto out; } len = strlen(dev_dirname); if (dev_dirname[len - 1] != '/') { dev_dirname[len] = '/'; dev_dirname[len + 1] = '\0'; } } ret = sem_init(&g_dpdk_sem, 0, 0); if (ret != 0) { SPDK_ERRLOG("Failed to initialize semaphore for rte_vhost pthread.\n"); ret = -1; goto out; } spdk_cpuset_zero(&g_vhost_core_mask); SPDK_ENV_FOREACH_CORE(i) { spdk_cpuset_set_cpu(&g_vhost_core_mask, i, true); } out: init_cb(ret); } static void vhost_fini(void *arg1) { struct spdk_vhost_dev *vdev, *tmp; spdk_vhost_lock(); vdev = spdk_vhost_dev_next(NULL); while (vdev != NULL) { tmp = spdk_vhost_dev_next(vdev); spdk_vhost_dev_remove(vdev); /* don't care if it fails, there's nothing we can do for now */ vdev = tmp; } spdk_vhost_unlock(); spdk_cpuset_zero(&g_vhost_core_mask); /* All devices are removed now. */ sem_destroy(&g_dpdk_sem); g_fini_cpl_cb(); } static void * session_shutdown(void *arg) { struct spdk_vhost_dev *vdev = NULL; TAILQ_FOREACH(vdev, &g_vhost_devices, tailq) { vhost_driver_unregister(vdev->path); vdev->registered = false; } SPDK_INFOLOG(vhost, "Exiting\n"); spdk_thread_send_msg(g_vhost_init_thread, vhost_fini, NULL); return NULL; } void spdk_vhost_fini(spdk_vhost_fini_cb fini_cb) { pthread_t tid; int rc; assert(spdk_get_thread() == g_vhost_init_thread); g_fini_cpl_cb = fini_cb; /* rte_vhost API for removing sockets is not asynchronous. Since it may call SPDK * ops for stopping a device or removing a connection, we need to call it from * a separate thread to avoid deadlock. */ rc = pthread_create(&tid, NULL, &session_shutdown, NULL); if (rc < 0) { SPDK_ERRLOG("Failed to start session shutdown thread (%d): %s\n", rc, spdk_strerror(rc)); abort(); } pthread_detach(tid); } void spdk_vhost_config_json(struct spdk_json_write_ctx *w) { struct spdk_vhost_dev *vdev; uint32_t delay_base_us; uint32_t iops_threshold; spdk_json_write_array_begin(w); spdk_vhost_lock(); vdev = spdk_vhost_dev_next(NULL); while (vdev != NULL) { vdev->backend->write_config_json(vdev, w); spdk_vhost_get_coalescing(vdev, &delay_base_us, &iops_threshold); if (delay_base_us) { spdk_json_write_object_begin(w); spdk_json_write_named_string(w, "method", "vhost_controller_set_coalescing"); spdk_json_write_named_object_begin(w, "params"); spdk_json_write_named_string(w, "ctrlr", vdev->name); spdk_json_write_named_uint32(w, "delay_base_us", delay_base_us); spdk_json_write_named_uint32(w, "iops_threshold", iops_threshold); spdk_json_write_object_end(w); spdk_json_write_object_end(w); } vdev = spdk_vhost_dev_next(vdev); } spdk_vhost_unlock(); spdk_json_write_array_end(w); } SPDK_LOG_REGISTER_COMPONENT(vhost) SPDK_LOG_REGISTER_COMPONENT(vhost_ring)