/* * Xen 9p backend * * Copyright Aporeto 2017 * * Authors: * Stefano Stabellini * */ #include "qemu/osdep.h" #include "hw/hw.h" #include "hw/9pfs/9p.h" #include "hw/xen/xen-legacy-backend.h" #include "hw/9pfs/xen-9pfs.h" #include "qapi/error.h" #include "qemu/config-file.h" #include "qemu/option.h" #include "fsdev/qemu-fsdev.h" #define VERSIONS "1" #define MAX_RINGS 8 #define MAX_RING_ORDER 8 typedef struct Xen9pfsRing { struct Xen9pfsDev *priv; int ref; xenevtchn_handle *evtchndev; int evtchn; int local_port; int ring_order; struct xen_9pfs_data_intf *intf; unsigned char *data; struct xen_9pfs_data ring; struct iovec *sg; QEMUBH *bh; /* local copies, so that we can read/write PDU data directly from * the ring */ RING_IDX out_cons, out_size, in_cons; bool inprogress; } Xen9pfsRing; typedef struct Xen9pfsDev { struct XenLegacyDevice xendev; /* must be first */ V9fsState state; char *path; char *security_model; char *tag; char *id; int num_rings; Xen9pfsRing *rings; } Xen9pfsDev; static void xen_9pfs_disconnect(struct XenLegacyDevice *xendev); static void xen_9pfs_in_sg(Xen9pfsRing *ring, struct iovec *in_sg, int *num, uint32_t idx, uint32_t size) { RING_IDX cons, prod, masked_prod, masked_cons; cons = ring->intf->in_cons; prod = ring->intf->in_prod; xen_rmb(); masked_prod = xen_9pfs_mask(prod, XEN_FLEX_RING_SIZE(ring->ring_order)); masked_cons = xen_9pfs_mask(cons, XEN_FLEX_RING_SIZE(ring->ring_order)); if (masked_prod < masked_cons) { in_sg[0].iov_base = ring->ring.in + masked_prod; in_sg[0].iov_len = masked_cons - masked_prod; *num = 1; } else { in_sg[0].iov_base = ring->ring.in + masked_prod; in_sg[0].iov_len = XEN_FLEX_RING_SIZE(ring->ring_order) - masked_prod; in_sg[1].iov_base = ring->ring.in; in_sg[1].iov_len = masked_cons; *num = 2; } } static void xen_9pfs_out_sg(Xen9pfsRing *ring, struct iovec *out_sg, int *num, uint32_t idx) { RING_IDX cons, prod, masked_prod, masked_cons; cons = ring->intf->out_cons; prod = ring->intf->out_prod; xen_rmb(); masked_prod = xen_9pfs_mask(prod, XEN_FLEX_RING_SIZE(ring->ring_order)); masked_cons = xen_9pfs_mask(cons, XEN_FLEX_RING_SIZE(ring->ring_order)); if (masked_cons < masked_prod) { out_sg[0].iov_base = ring->ring.out + masked_cons; out_sg[0].iov_len = ring->out_size; *num = 1; } else { if (ring->out_size > (XEN_FLEX_RING_SIZE(ring->ring_order) - masked_cons)) { out_sg[0].iov_base = ring->ring.out + masked_cons; out_sg[0].iov_len = XEN_FLEX_RING_SIZE(ring->ring_order) - masked_cons; out_sg[1].iov_base = ring->ring.out; out_sg[1].iov_len = ring->out_size - (XEN_FLEX_RING_SIZE(ring->ring_order) - masked_cons); *num = 2; } else { out_sg[0].iov_base = ring->ring.out + masked_cons; out_sg[0].iov_len = ring->out_size; *num = 1; } } } static ssize_t xen_9pfs_pdu_vmarshal(V9fsPDU *pdu, size_t offset, const char *fmt, va_list ap) { Xen9pfsDev *xen_9pfs = container_of(pdu->s, Xen9pfsDev, state); struct iovec in_sg[2]; int num; ssize_t ret; xen_9pfs_in_sg(&xen_9pfs->rings[pdu->tag % xen_9pfs->num_rings], in_sg, &num, pdu->idx, ROUND_UP(offset + 128, 512)); ret = v9fs_iov_vmarshal(in_sg, num, offset, 0, fmt, ap); if (ret < 0) { xen_pv_printf(&xen_9pfs->xendev, 0, "Failed to encode VirtFS request type %d\n", pdu->id + 1); xen_be_set_state(&xen_9pfs->xendev, XenbusStateClosing); xen_9pfs_disconnect(&xen_9pfs->xendev); } return ret; } static ssize_t xen_9pfs_pdu_vunmarshal(V9fsPDU *pdu, size_t offset, const char *fmt, va_list ap) { Xen9pfsDev *xen_9pfs = container_of(pdu->s, Xen9pfsDev, state); struct iovec out_sg[2]; int num; ssize_t ret; xen_9pfs_out_sg(&xen_9pfs->rings[pdu->tag % xen_9pfs->num_rings], out_sg, &num, pdu->idx); ret = v9fs_iov_vunmarshal(out_sg, num, offset, 0, fmt, ap); if (ret < 0) { xen_pv_printf(&xen_9pfs->xendev, 0, "Failed to decode VirtFS request type %d\n", pdu->id); xen_be_set_state(&xen_9pfs->xendev, XenbusStateClosing); xen_9pfs_disconnect(&xen_9pfs->xendev); } return ret; } static void xen_9pfs_init_out_iov_from_pdu(V9fsPDU *pdu, struct iovec **piov, unsigned int *pniov, size_t size) { Xen9pfsDev *xen_9pfs = container_of(pdu->s, Xen9pfsDev, state); Xen9pfsRing *ring = &xen_9pfs->rings[pdu->tag % xen_9pfs->num_rings]; int num; g_free(ring->sg); ring->sg = g_new0(struct iovec, 2); xen_9pfs_out_sg(ring, ring->sg, &num, pdu->idx); *piov = ring->sg; *pniov = num; } static void xen_9pfs_init_in_iov_from_pdu(V9fsPDU *pdu, struct iovec **piov, unsigned int *pniov, size_t size) { Xen9pfsDev *xen_9pfs = container_of(pdu->s, Xen9pfsDev, state); Xen9pfsRing *ring = &xen_9pfs->rings[pdu->tag % xen_9pfs->num_rings]; int num; size_t buf_size; g_free(ring->sg); ring->sg = g_new0(struct iovec, 2); xen_9pfs_in_sg(ring, ring->sg, &num, pdu->idx, size); buf_size = iov_size(ring->sg, num); if (buf_size < size) { xen_pv_printf(&xen_9pfs->xendev, 0, "Xen 9pfs request type %d" "needs %zu bytes, buffer has %zu\n", pdu->id, size, buf_size); xen_be_set_state(&xen_9pfs->xendev, XenbusStateClosing); xen_9pfs_disconnect(&xen_9pfs->xendev); } *piov = ring->sg; *pniov = num; } static void xen_9pfs_push_and_notify(V9fsPDU *pdu) { RING_IDX prod; Xen9pfsDev *priv = container_of(pdu->s, Xen9pfsDev, state); Xen9pfsRing *ring = &priv->rings[pdu->tag % priv->num_rings]; g_free(ring->sg); ring->sg = NULL; ring->intf->out_cons = ring->out_cons; xen_wmb(); prod = ring->intf->in_prod; xen_rmb(); ring->intf->in_prod = prod + pdu->size; xen_wmb(); ring->inprogress = false; xenevtchn_notify(ring->evtchndev, ring->local_port); qemu_bh_schedule(ring->bh); } static const V9fsTransport xen_9p_transport = { .pdu_vmarshal = xen_9pfs_pdu_vmarshal, .pdu_vunmarshal = xen_9pfs_pdu_vunmarshal, .init_in_iov_from_pdu = xen_9pfs_init_in_iov_from_pdu, .init_out_iov_from_pdu = xen_9pfs_init_out_iov_from_pdu, .push_and_notify = xen_9pfs_push_and_notify, }; static int xen_9pfs_init(struct XenLegacyDevice *xendev) { return 0; } static int xen_9pfs_receive(Xen9pfsRing *ring) { P9MsgHeader h; RING_IDX cons, prod, masked_prod, masked_cons, queued; V9fsPDU *pdu; if (ring->inprogress) { return 0; } cons = ring->intf->out_cons; prod = ring->intf->out_prod; xen_rmb(); queued = xen_9pfs_queued(prod, cons, XEN_FLEX_RING_SIZE(ring->ring_order)); if (queued < sizeof(h)) { return 0; } ring->inprogress = true; masked_prod = xen_9pfs_mask(prod, XEN_FLEX_RING_SIZE(ring->ring_order)); masked_cons = xen_9pfs_mask(cons, XEN_FLEX_RING_SIZE(ring->ring_order)); xen_9pfs_read_packet((uint8_t *) &h, ring->ring.out, sizeof(h), masked_prod, &masked_cons, XEN_FLEX_RING_SIZE(ring->ring_order)); if (queued < le32_to_cpu(h.size_le)) { return 0; } /* cannot fail, because we only handle one request per ring at a time */ pdu = pdu_alloc(&ring->priv->state); ring->out_size = le32_to_cpu(h.size_le); ring->out_cons = cons + le32_to_cpu(h.size_le); pdu_submit(pdu, &h); return 0; } static void xen_9pfs_bh(void *opaque) { Xen9pfsRing *ring = opaque; xen_9pfs_receive(ring); } static void xen_9pfs_evtchn_event(void *opaque) { Xen9pfsRing *ring = opaque; evtchn_port_t port; port = xenevtchn_pending(ring->evtchndev); xenevtchn_unmask(ring->evtchndev, port); qemu_bh_schedule(ring->bh); } static void xen_9pfs_disconnect(struct XenLegacyDevice *xendev) { Xen9pfsDev *xen_9pdev = container_of(xendev, Xen9pfsDev, xendev); int i; for (i = 0; i < xen_9pdev->num_rings; i++) { if (xen_9pdev->rings[i].evtchndev != NULL) { qemu_set_fd_handler(xenevtchn_fd(xen_9pdev->rings[i].evtchndev), NULL, NULL, NULL); xenevtchn_unbind(xen_9pdev->rings[i].evtchndev, xen_9pdev->rings[i].local_port); xen_9pdev->rings[i].evtchndev = NULL; } } } static int xen_9pfs_free(struct XenLegacyDevice *xendev) { Xen9pfsDev *xen_9pdev = container_of(xendev, Xen9pfsDev, xendev); int i; if (xen_9pdev->rings[0].evtchndev != NULL) { xen_9pfs_disconnect(xendev); } for (i = 0; i < xen_9pdev->num_rings; i++) { if (xen_9pdev->rings[i].data != NULL) { xen_be_unmap_grant_refs(&xen_9pdev->xendev, xen_9pdev->rings[i].data, (1 << xen_9pdev->rings[i].ring_order)); } if (xen_9pdev->rings[i].intf != NULL) { xen_be_unmap_grant_refs(&xen_9pdev->xendev, xen_9pdev->rings[i].intf, 1); } if (xen_9pdev->rings[i].bh != NULL) { qemu_bh_delete(xen_9pdev->rings[i].bh); } } g_free(xen_9pdev->id); g_free(xen_9pdev->tag); g_free(xen_9pdev->path); g_free(xen_9pdev->security_model); g_free(xen_9pdev->rings); return 0; } static int xen_9pfs_connect(struct XenLegacyDevice *xendev) { Error *err = NULL; int i; Xen9pfsDev *xen_9pdev = container_of(xendev, Xen9pfsDev, xendev); V9fsState *s = &xen_9pdev->state; QemuOpts *fsdev; if (xenstore_read_fe_int(&xen_9pdev->xendev, "num-rings", &xen_9pdev->num_rings) == -1 || xen_9pdev->num_rings > MAX_RINGS || xen_9pdev->num_rings < 1) { return -1; } xen_9pdev->rings = g_new0(Xen9pfsRing, xen_9pdev->num_rings); for (i = 0; i < xen_9pdev->num_rings; i++) { char *str; int ring_order; xen_9pdev->rings[i].priv = xen_9pdev; xen_9pdev->rings[i].evtchn = -1; xen_9pdev->rings[i].local_port = -1; str = g_strdup_printf("ring-ref%u", i); if (xenstore_read_fe_int(&xen_9pdev->xendev, str, &xen_9pdev->rings[i].ref) == -1) { g_free(str); goto out; } g_free(str); str = g_strdup_printf("event-channel-%u", i); if (xenstore_read_fe_int(&xen_9pdev->xendev, str, &xen_9pdev->rings[i].evtchn) == -1) { g_free(str); goto out; } g_free(str); xen_9pdev->rings[i].intf = xen_be_map_grant_ref(&xen_9pdev->xendev, xen_9pdev->rings[i].ref, PROT_READ | PROT_WRITE); if (!xen_9pdev->rings[i].intf) { goto out; } ring_order = xen_9pdev->rings[i].intf->ring_order; if (ring_order > MAX_RING_ORDER) { goto out; } xen_9pdev->rings[i].ring_order = ring_order; xen_9pdev->rings[i].data = xen_be_map_grant_refs(&xen_9pdev->xendev, xen_9pdev->rings[i].intf->ref, (1 << ring_order), PROT_READ | PROT_WRITE); if (!xen_9pdev->rings[i].data) { goto out; } xen_9pdev->rings[i].ring.in = xen_9pdev->rings[i].data; xen_9pdev->rings[i].ring.out = xen_9pdev->rings[i].data + XEN_FLEX_RING_SIZE(ring_order); xen_9pdev->rings[i].bh = qemu_bh_new(xen_9pfs_bh, &xen_9pdev->rings[i]); xen_9pdev->rings[i].out_cons = 0; xen_9pdev->rings[i].out_size = 0; xen_9pdev->rings[i].inprogress = false; xen_9pdev->rings[i].evtchndev = xenevtchn_open(NULL, 0); if (xen_9pdev->rings[i].evtchndev == NULL) { goto out; } qemu_set_cloexec(xenevtchn_fd(xen_9pdev->rings[i].evtchndev)); xen_9pdev->rings[i].local_port = xenevtchn_bind_interdomain (xen_9pdev->rings[i].evtchndev, xendev->dom, xen_9pdev->rings[i].evtchn); if (xen_9pdev->rings[i].local_port == -1) { xen_pv_printf(xendev, 0, "xenevtchn_bind_interdomain failed port=%d\n", xen_9pdev->rings[i].evtchn); goto out; } xen_pv_printf(xendev, 2, "bind evtchn port %d\n", xendev->local_port); qemu_set_fd_handler(xenevtchn_fd(xen_9pdev->rings[i].evtchndev), xen_9pfs_evtchn_event, NULL, &xen_9pdev->rings[i]); } xen_9pdev->security_model = xenstore_read_be_str(xendev, "security_model"); xen_9pdev->path = xenstore_read_be_str(xendev, "path"); xen_9pdev->id = s->fsconf.fsdev_id = g_strdup_printf("xen9p%d", xendev->dev); xen_9pdev->tag = s->fsconf.tag = xenstore_read_fe_str(xendev, "tag"); fsdev = qemu_opts_create(qemu_find_opts("fsdev"), s->fsconf.tag, 1, NULL); qemu_opt_set(fsdev, "fsdriver", "local", NULL); qemu_opt_set(fsdev, "path", xen_9pdev->path, NULL); qemu_opt_set(fsdev, "security_model", xen_9pdev->security_model, NULL); qemu_opts_set_id(fsdev, s->fsconf.fsdev_id); qemu_fsdev_add(fsdev, &err); if (err) { error_report_err(err); } v9fs_device_realize_common(s, &xen_9p_transport, NULL); return 0; out: xen_9pfs_free(xendev); return -1; } static void xen_9pfs_alloc(struct XenLegacyDevice *xendev) { xenstore_write_be_str(xendev, "versions", VERSIONS); xenstore_write_be_int(xendev, "max-rings", MAX_RINGS); xenstore_write_be_int(xendev, "max-ring-page-order", MAX_RING_ORDER); } struct XenDevOps xen_9pfs_ops = { .size = sizeof(Xen9pfsDev), .flags = DEVOPS_FLAG_NEED_GNTDEV, .alloc = xen_9pfs_alloc, .init = xen_9pfs_init, .initialise = xen_9pfs_connect, .disconnect = xen_9pfs_disconnect, .free = xen_9pfs_free, };