/*- * Copyright (c) 2011, Bryan Venteicher * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice unmodified, this list of conditions, and the following * disclaimer. * 2. 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. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 AUTHOR 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. */ /* * Implements the virtqueue interface as basically described * in the original VirtIO paper. */ #include __FBSDID("$FreeBSD$"); #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "virtio_bus_if.h" struct virtqueue { device_t vq_dev; char vq_name[VIRTQUEUE_MAX_NAME_SZ]; uint16_t vq_queue_index; uint16_t vq_nentries; uint32_t vq_flags; #define VIRTQUEUE_FLAG_INDIRECT 0x0001 #define VIRTQUEUE_FLAG_EVENT_IDX 0x0002 int vq_alignment; int vq_ring_size; void *vq_ring_mem; int vq_max_indirect_size; int vq_indirect_mem_size; virtqueue_intr_t *vq_intrhand; void *vq_intrhand_arg; struct vring vq_ring; uint16_t vq_free_cnt; uint16_t vq_queued_cnt; /* * Head of the free chain in the descriptor table. If * there are no free descriptors, this will be set to * VQ_RING_DESC_CHAIN_END. */ uint16_t vq_desc_head_idx; /* * Last consumed descriptor in the used table, * trails vq_ring.used->idx. */ uint16_t vq_used_cons_idx; struct vq_desc_extra { void *cookie; struct vring_desc *indirect; vm_paddr_t indirect_paddr; uint16_t ndescs; } vq_descx[0]; }; /* * The maximum virtqueue size is 2^15. Use that value as the end of * descriptor chain terminator since it will never be a valid index * in the descriptor table. This is used to verify we are correctly * handling vq_free_cnt. */ #define VQ_RING_DESC_CHAIN_END 32768 #define VQASSERT(_vq, _exp, _msg, ...) \ KASSERT((_exp),("%s: %s - "_msg, __func__, (_vq)->vq_name, \ ##__VA_ARGS__)) #define VQ_RING_ASSERT_VALID_IDX(_vq, _idx) \ VQASSERT((_vq), (_idx) < (_vq)->vq_nentries, \ "invalid ring index: %d, max: %d", (_idx), \ (_vq)->vq_nentries) #define VQ_RING_ASSERT_CHAIN_TERM(_vq) \ VQASSERT((_vq), (_vq)->vq_desc_head_idx == \ VQ_RING_DESC_CHAIN_END, "full ring terminated " \ "incorrectly: head idx: %d", (_vq)->vq_desc_head_idx) static int virtqueue_init_indirect(struct virtqueue *vq, int); static void virtqueue_free_indirect(struct virtqueue *vq); static void virtqueue_init_indirect_list(struct virtqueue *, struct vring_desc *); static void vq_ring_init(struct virtqueue *); static void vq_ring_update_avail(struct virtqueue *, uint16_t); static uint16_t vq_ring_enqueue_segments(struct virtqueue *, struct vring_desc *, uint16_t, struct sglist *, int, int); static int vq_ring_use_indirect(struct virtqueue *, int); static void vq_ring_enqueue_indirect(struct virtqueue *, void *, struct sglist *, int, int); static int vq_ring_enable_interrupt(struct virtqueue *, uint16_t); static int vq_ring_must_notify_host(struct virtqueue *); static void vq_ring_notify_host(struct virtqueue *); static void vq_ring_free_chain(struct virtqueue *, uint16_t); uint64_t virtqueue_filter_features(uint64_t features) { uint64_t mask; mask = (1 << VIRTIO_TRANSPORT_F_START) - 1; mask |= VIRTIO_RING_F_INDIRECT_DESC; mask |= VIRTIO_RING_F_EVENT_IDX; return (features & mask); } int virtqueue_alloc(device_t dev, uint16_t queue, uint16_t size, int align, vm_paddr_t highaddr, struct vq_alloc_info *info, struct virtqueue **vqp) { struct virtqueue *vq; int error; *vqp = NULL; error = 0; if (size == 0) { device_printf(dev, "virtqueue %d (%s) does not exist (size is zero)\n", queue, info->vqai_name); return (ENODEV); } else if (!powerof2(size)) { device_printf(dev, "virtqueue %d (%s) size is not a power of 2: %d\n", queue, info->vqai_name, size); return (ENXIO); } else if (info->vqai_maxindirsz > VIRTIO_MAX_INDIRECT) { device_printf(dev, "virtqueue %d (%s) requested too many " "indirect descriptors: %d, max %d\n", queue, info->vqai_name, info->vqai_maxindirsz, VIRTIO_MAX_INDIRECT); return (EINVAL); } vq = malloc(sizeof(struct virtqueue) + size * sizeof(struct vq_desc_extra), M_DEVBUF, M_NOWAIT | M_ZERO); if (vq == NULL) { device_printf(dev, "cannot allocate virtqueue\n"); return (ENOMEM); } vq->vq_dev = dev; strlcpy(vq->vq_name, info->vqai_name, sizeof(vq->vq_name)); vq->vq_queue_index = queue; vq->vq_alignment = align; vq->vq_nentries = size; vq->vq_free_cnt = size; vq->vq_intrhand = info->vqai_intr; vq->vq_intrhand_arg = info->vqai_intr_arg; if (VIRTIO_BUS_WITH_FEATURE(dev, VIRTIO_RING_F_EVENT_IDX) != 0) vq->vq_flags |= VIRTQUEUE_FLAG_EVENT_IDX; if (info->vqai_maxindirsz > 1) { error = virtqueue_init_indirect(vq, info->vqai_maxindirsz); if (error) goto fail; } vq->vq_ring_size = round_page(vring_size(size, align)); vq->vq_ring_mem = contigmalloc(vq->vq_ring_size, M_DEVBUF, M_NOWAIT | M_ZERO, 0, highaddr, PAGE_SIZE, 0); if (vq->vq_ring_mem == NULL) { device_printf(dev, "cannot allocate memory for virtqueue ring\n"); error = ENOMEM; goto fail; } vq_ring_init(vq); virtqueue_disable_intr(vq); *vqp = vq; fail: if (error) virtqueue_free(vq); return (error); } static int virtqueue_init_indirect(struct virtqueue *vq, int indirect_size) { device_t dev; struct vq_desc_extra *dxp; int i, size; dev = vq->vq_dev; if (VIRTIO_BUS_WITH_FEATURE(dev, VIRTIO_RING_F_INDIRECT_DESC) == 0) { /* * Indirect descriptors requested by the driver but not * negotiated. Return zero to keep the initialization * going: we'll run fine without. */ if (bootverbose) device_printf(dev, "virtqueue %d (%s) requested " "indirect descriptors but not negotiated\n", vq->vq_queue_index, vq->vq_name); return (0); } size = indirect_size * sizeof(struct vring_desc); vq->vq_max_indirect_size = indirect_size; vq->vq_indirect_mem_size = size; vq->vq_flags |= VIRTQUEUE_FLAG_INDIRECT; for (i = 0; i < vq->vq_nentries; i++) { dxp = &vq->vq_descx[i]; dxp->indirect = malloc(size, M_DEVBUF, M_NOWAIT); if (dxp->indirect == NULL) { device_printf(dev, "cannot allocate indirect list\n"); return (ENOMEM); } dxp->indirect_paddr = vtophys(dxp->indirect); virtqueue_init_indirect_list(vq, dxp->indirect); } return (0); } static void virtqueue_free_indirect(struct virtqueue *vq) { struct vq_desc_extra *dxp; int i; for (i = 0; i < vq->vq_nentries; i++) { dxp = &vq->vq_descx[i]; if (dxp->indirect == NULL) break; free(dxp->indirect, M_DEVBUF); dxp->indirect = NULL; dxp->indirect_paddr = 0; } vq->vq_flags &= ~VIRTQUEUE_FLAG_INDIRECT; vq->vq_indirect_mem_size = 0; } static void virtqueue_init_indirect_list(struct virtqueue *vq, struct vring_desc *indirect) { int i; bzero(indirect, vq->vq_indirect_mem_size); for (i = 0; i < vq->vq_max_indirect_size - 1; i++) indirect[i].next = i + 1; indirect[i].next = VQ_RING_DESC_CHAIN_END; } int virtqueue_reinit(struct virtqueue *vq, uint16_t size) { struct vq_desc_extra *dxp; int i; if (vq->vq_nentries != size) { device_printf(vq->vq_dev, "%s: '%s' changed size; old=%hu, new=%hu\n", __func__, vq->vq_name, vq->vq_nentries, size); return (EINVAL); } /* Warn if the virtqueue was not properly cleaned up. */ if (vq->vq_free_cnt != vq->vq_nentries) { device_printf(vq->vq_dev, "%s: warning '%s' virtqueue not empty, " "leaking %d entries\n", __func__, vq->vq_name, vq->vq_nentries - vq->vq_free_cnt); } vq->vq_desc_head_idx = 0; vq->vq_used_cons_idx = 0; vq->vq_queued_cnt = 0; vq->vq_free_cnt = vq->vq_nentries; /* To be safe, reset all our allocated memory. */ bzero(vq->vq_ring_mem, vq->vq_ring_size); for (i = 0; i < vq->vq_nentries; i++) { dxp = &vq->vq_descx[i]; dxp->cookie = NULL; dxp->ndescs = 0; if (vq->vq_flags & VIRTQUEUE_FLAG_INDIRECT) virtqueue_init_indirect_list(vq, dxp->indirect); } vq_ring_init(vq); virtqueue_disable_intr(vq); return (0); } void virtqueue_free(struct virtqueue *vq) { if (vq->vq_free_cnt != vq->vq_nentries) { device_printf(vq->vq_dev, "%s: freeing non-empty virtqueue, " "leaking %d entries\n", vq->vq_name, vq->vq_nentries - vq->vq_free_cnt); } if (vq->vq_flags & VIRTQUEUE_FLAG_INDIRECT) virtqueue_free_indirect(vq); if (vq->vq_ring_mem != NULL) { contigfree(vq->vq_ring_mem, vq->vq_ring_size, M_DEVBUF); vq->vq_ring_size = 0; vq->vq_ring_mem = NULL; } free(vq, M_DEVBUF); } vm_paddr_t virtqueue_paddr(struct virtqueue *vq) { return (vtophys(vq->vq_ring_mem)); } int virtqueue_size(struct virtqueue *vq) { return (vq->vq_nentries); } int virtqueue_empty(struct virtqueue *vq) { return (vq->vq_nentries == vq->vq_free_cnt); } int virtqueue_full(struct virtqueue *vq) { return (vq->vq_free_cnt == 0); } void virtqueue_notify(struct virtqueue *vq) { /* Ensure updated avail->idx is visible to host. */ mb(); if (vq_ring_must_notify_host(vq)) vq_ring_notify_host(vq); vq->vq_queued_cnt = 0; } int virtqueue_nused(struct virtqueue *vq) { uint16_t used_idx, nused; used_idx = vq->vq_ring.used->idx; nused = (uint16_t)(used_idx - vq->vq_used_cons_idx); VQASSERT(vq, nused <= vq->vq_nentries, "used more than available"); return (nused); } int virtqueue_intr_filter(struct virtqueue *vq) { if (vq->vq_used_cons_idx == vq->vq_ring.used->idx) return (0); virtqueue_disable_intr(vq); return (1); } void virtqueue_intr(struct virtqueue *vq) { vq->vq_intrhand(vq->vq_intrhand_arg); } int virtqueue_enable_intr(struct virtqueue *vq) { return (vq_ring_enable_interrupt(vq, 0)); } int virtqueue_postpone_intr(struct virtqueue *vq, vq_postpone_t hint) { uint16_t ndesc, avail_idx; avail_idx = vq->vq_ring.avail->idx; ndesc = (uint16_t)(avail_idx - vq->vq_used_cons_idx); switch (hint) { case VQ_POSTPONE_SHORT: ndesc /= 4; break; case VQ_POSTPONE_LONG: ndesc *= 3 / 4; break; case VQ_POSTPONE_EMPTIED: break; } return (vq_ring_enable_interrupt(vq, ndesc)); } /* * Note this is only considered a hint to the host. */ void virtqueue_disable_intr(struct virtqueue *vq) { if (vq->vq_flags & VIRTQUEUE_FLAG_EVENT_IDX) { vring_used_event(&vq->vq_ring) = vq->vq_used_cons_idx - vq->vq_nentries - 1; } else vq->vq_ring.avail->flags |= VRING_AVAIL_F_NO_INTERRUPT; } int virtqueue_enqueue(struct virtqueue *vq, void *cookie, struct sglist *sg, int readable, int writable) { struct vq_desc_extra *dxp; int needed; uint16_t head_idx, idx; needed = readable + writable; VQASSERT(vq, cookie != NULL, "enqueuing with no cookie"); VQASSERT(vq, needed == sg->sg_nseg, "segment count mismatch, %d, %d", needed, sg->sg_nseg); VQASSERT(vq, needed <= vq->vq_nentries || needed <= vq->vq_max_indirect_size, "too many segments to enqueue: %d, %d/%d", needed, vq->vq_nentries, vq->vq_max_indirect_size); if (needed < 1) return (EINVAL); if (vq->vq_free_cnt == 0) return (ENOSPC); if (vq_ring_use_indirect(vq, needed)) { vq_ring_enqueue_indirect(vq, cookie, sg, readable, writable); return (0); } else if (vq->vq_free_cnt < needed) return (EMSGSIZE); head_idx = vq->vq_desc_head_idx; VQ_RING_ASSERT_VALID_IDX(vq, head_idx); dxp = &vq->vq_descx[head_idx]; VQASSERT(vq, dxp->cookie == NULL, "cookie already exists for index %d", head_idx); dxp->cookie = cookie; dxp->ndescs = needed; idx = vq_ring_enqueue_segments(vq, vq->vq_ring.desc, head_idx, sg, readable, writable); vq->vq_desc_head_idx = idx; vq->vq_free_cnt -= needed; if (vq->vq_free_cnt == 0) VQ_RING_ASSERT_CHAIN_TERM(vq); else VQ_RING_ASSERT_VALID_IDX(vq, idx); vq_ring_update_avail(vq, head_idx); return (0); } void * virtqueue_dequeue(struct virtqueue *vq, uint32_t *len) { struct vring_used_elem *uep; void *cookie; uint16_t used_idx, desc_idx; if (vq->vq_used_cons_idx == vq->vq_ring.used->idx) return (NULL); used_idx = vq->vq_used_cons_idx++ & (vq->vq_nentries - 1); uep = &vq->vq_ring.used->ring[used_idx]; rmb(); desc_idx = (uint16_t) uep->id; if (len != NULL) *len = uep->len; vq_ring_free_chain(vq, desc_idx); cookie = vq->vq_descx[desc_idx].cookie; VQASSERT(vq, cookie != NULL, "no cookie for index %d", desc_idx); vq->vq_descx[desc_idx].cookie = NULL; return (cookie); } void * virtqueue_poll(struct virtqueue *vq, uint32_t *len) { void *cookie; while ((cookie = virtqueue_dequeue(vq, len)) == NULL) cpu_spinwait(); return (cookie); } void * virtqueue_drain(struct virtqueue *vq, int *last) { void *cookie; int idx; cookie = NULL; idx = *last; while (idx < vq->vq_nentries && cookie == NULL) { if ((cookie = vq->vq_descx[idx].cookie) != NULL) { vq->vq_descx[idx].cookie = NULL; /* Free chain to keep free count consistent. */ vq_ring_free_chain(vq, idx); } idx++; } *last = idx; return (cookie); } void virtqueue_dump(struct virtqueue *vq) { if (vq == NULL) return; printf("VQ: %s - size=%d; free=%d; used=%d; queued=%d; " "desc_head_idx=%d; avail.idx=%d; used_cons_idx=%d; " "used.idx=%d; avail.flags=0x%x; used.flags=0x%x\n", vq->vq_name, vq->vq_nentries, vq->vq_free_cnt, virtqueue_nused(vq), vq->vq_queued_cnt, vq->vq_desc_head_idx, vq->vq_ring.avail->idx, vq->vq_used_cons_idx, vq->vq_ring.used->idx, vq->vq_ring.avail->flags, vq->vq_ring.used->flags); } static void vq_ring_init(struct virtqueue *vq) { struct vring *vr; char *ring_mem; int i, size; ring_mem = vq->vq_ring_mem; size = vq->vq_nentries; vr = &vq->vq_ring; vring_init(vr, size, ring_mem, vq->vq_alignment); for (i = 0; i < size - 1; i++) vr->desc[i].next = i + 1; vr->desc[i].next = VQ_RING_DESC_CHAIN_END; } static void vq_ring_update_avail(struct virtqueue *vq, uint16_t desc_idx) { uint16_t avail_idx; /* * Place the head of the descriptor chain into the next slot and make * it usable to the host. The chain is made available now rather than * deferring to virtqueue_notify() in the hopes that if the host is * currently running on another CPU, we can keep it processing the new * descriptor. */ avail_idx = vq->vq_ring.avail->idx & (vq->vq_nentries - 1); vq->vq_ring.avail->ring[avail_idx] = desc_idx; wmb(); vq->vq_ring.avail->idx++; /* Keep pending count until virtqueue_notify(). */ vq->vq_queued_cnt++; } static uint16_t vq_ring_enqueue_segments(struct virtqueue *vq, struct vring_desc *desc, uint16_t head_idx, struct sglist *sg, int readable, int writable) { struct sglist_seg *seg; struct vring_desc *dp; int i, needed; uint16_t idx; needed = readable + writable; for (i = 0, idx = head_idx, seg = sg->sg_segs; i < needed; i++, idx = dp->next, seg++) { VQASSERT(vq, idx != VQ_RING_DESC_CHAIN_END, "premature end of free desc chain"); dp = &desc[idx]; dp->addr = seg->ss_paddr; dp->len = seg->ss_len; dp->flags = 0; if (i < needed - 1) dp->flags |= VRING_DESC_F_NEXT; if (i >= readable) dp->flags |= VRING_DESC_F_WRITE; } return (idx); } static int vq_ring_use_indirect(struct virtqueue *vq, int needed) { if ((vq->vq_flags & VIRTQUEUE_FLAG_INDIRECT) == 0) return (0); if (vq->vq_max_indirect_size < needed) return (0); if (needed < 2) return (0); return (1); } static void vq_ring_enqueue_indirect(struct virtqueue *vq, void *cookie, struct sglist *sg, int readable, int writable) { struct vring_desc *dp; struct vq_desc_extra *dxp; int needed; uint16_t head_idx; needed = readable + writable; VQASSERT(vq, needed <= vq->vq_max_indirect_size, "enqueuing too many indirect descriptors"); head_idx = vq->vq_desc_head_idx; VQ_RING_ASSERT_VALID_IDX(vq, head_idx); dp = &vq->vq_ring.desc[head_idx]; dxp = &vq->vq_descx[head_idx]; VQASSERT(vq, dxp->cookie == NULL, "cookie already exists for index %d", head_idx); dxp->cookie = cookie; dxp->ndescs = 1; dp->addr = dxp->indirect_paddr; dp->len = needed * sizeof(struct vring_desc); dp->flags = VRING_DESC_F_INDIRECT; vq_ring_enqueue_segments(vq, dxp->indirect, 0, sg, readable, writable); vq->vq_desc_head_idx = dp->next; vq->vq_free_cnt--; if (vq->vq_free_cnt == 0) VQ_RING_ASSERT_CHAIN_TERM(vq); else VQ_RING_ASSERT_VALID_IDX(vq, vq->vq_desc_head_idx); vq_ring_update_avail(vq, head_idx); } static int vq_ring_enable_interrupt(struct virtqueue *vq, uint16_t ndesc) { /* * Enable interrupts, making sure we get the latest index of * what's already been consumed. */ if (vq->vq_flags & VIRTQUEUE_FLAG_EVENT_IDX) vring_used_event(&vq->vq_ring) = vq->vq_used_cons_idx + ndesc; else vq->vq_ring.avail->flags &= ~VRING_AVAIL_F_NO_INTERRUPT; mb(); /* * Enough items may have already been consumed to meet our threshold * since we last checked. Let our caller know so it processes the new * entries. */ if (virtqueue_nused(vq) > ndesc) return (1); return (0); } static int vq_ring_must_notify_host(struct virtqueue *vq) { uint16_t new_idx, prev_idx, event_idx; if (vq->vq_flags & VIRTQUEUE_FLAG_EVENT_IDX) { new_idx = vq->vq_ring.avail->idx; prev_idx = new_idx - vq->vq_queued_cnt; event_idx = vring_avail_event(&vq->vq_ring); return (vring_need_event(event_idx, new_idx, prev_idx) != 0); } return ((vq->vq_ring.used->flags & VRING_USED_F_NO_NOTIFY) == 0); } static void vq_ring_notify_host(struct virtqueue *vq) { VIRTIO_BUS_NOTIFY_VQ(vq->vq_dev, vq->vq_queue_index); } static void vq_ring_free_chain(struct virtqueue *vq, uint16_t desc_idx) { struct vring_desc *dp; struct vq_desc_extra *dxp; VQ_RING_ASSERT_VALID_IDX(vq, desc_idx); dp = &vq->vq_ring.desc[desc_idx]; dxp = &vq->vq_descx[desc_idx]; if (vq->vq_free_cnt == 0) VQ_RING_ASSERT_CHAIN_TERM(vq); vq->vq_free_cnt += dxp->ndescs; dxp->ndescs--; if ((dp->flags & VRING_DESC_F_INDIRECT) == 0) { while (dp->flags & VRING_DESC_F_NEXT) { VQ_RING_ASSERT_VALID_IDX(vq, dp->next); dp = &vq->vq_ring.desc[dp->next]; dxp->ndescs--; } } VQASSERT(vq, dxp->ndescs == 0, "failed to free entire desc chain, remaining: %d", dxp->ndescs); /* * We must append the existing free chain, if any, to the end of * newly freed chain. If the virtqueue was completely used, then * head would be VQ_RING_DESC_CHAIN_END (ASSERTed above). */ dp->next = vq->vq_desc_head_idx; vq->vq_desc_head_idx = desc_idx; }