#include "qemu/osdep.h" #include "hw/hw.h" #include "qapi/error.h" #include "qemu/error-report.h" #include "hw/scsi/scsi.h" #include "block/scsi.h" #include "hw/qdev.h" #include "sysemu/block-backend.h" #include "sysemu/blockdev.h" #include "trace.h" #include "sysemu/dma.h" #include "qemu/cutils.h" static char *scsibus_get_dev_path(DeviceState *dev); static char *scsibus_get_fw_dev_path(DeviceState *dev); static void scsi_req_dequeue(SCSIRequest *req); static uint8_t *scsi_target_alloc_buf(SCSIRequest *req, size_t len); static void scsi_target_free_buf(SCSIRequest *req); static Property scsi_props[] = { DEFINE_PROP_UINT32("channel", SCSIDevice, channel, 0), DEFINE_PROP_UINT32("scsi-id", SCSIDevice, id, -1), DEFINE_PROP_UINT32("lun", SCSIDevice, lun, -1), DEFINE_PROP_END_OF_LIST(), }; static void scsi_bus_class_init(ObjectClass *klass, void *data) { BusClass *k = BUS_CLASS(klass); HotplugHandlerClass *hc = HOTPLUG_HANDLER_CLASS(klass); k->get_dev_path = scsibus_get_dev_path; k->get_fw_dev_path = scsibus_get_fw_dev_path; hc->unplug = qdev_simple_device_unplug_cb; } static const TypeInfo scsi_bus_info = { .name = TYPE_SCSI_BUS, .parent = TYPE_BUS, .instance_size = sizeof(SCSIBus), .class_init = scsi_bus_class_init, .interfaces = (InterfaceInfo[]) { { TYPE_HOTPLUG_HANDLER }, { } } }; static int next_scsi_bus; static void scsi_device_realize(SCSIDevice *s, Error **errp) { SCSIDeviceClass *sc = SCSI_DEVICE_GET_CLASS(s); if (sc->realize) { sc->realize(s, errp); } } int scsi_bus_parse_cdb(SCSIDevice *dev, SCSICommand *cmd, uint8_t *buf, void *hba_private) { SCSIBus *bus = DO_UPCAST(SCSIBus, qbus, dev->qdev.parent_bus); int rc; assert(cmd->len == 0); rc = scsi_req_parse_cdb(dev, cmd, buf); if (bus->info->parse_cdb) { rc = bus->info->parse_cdb(dev, cmd, buf, hba_private); } return rc; } static SCSIRequest *scsi_device_alloc_req(SCSIDevice *s, uint32_t tag, uint32_t lun, uint8_t *buf, void *hba_private) { SCSIDeviceClass *sc = SCSI_DEVICE_GET_CLASS(s); if (sc->alloc_req) { return sc->alloc_req(s, tag, lun, buf, hba_private); } return NULL; } void scsi_device_unit_attention_reported(SCSIDevice *s) { SCSIDeviceClass *sc = SCSI_DEVICE_GET_CLASS(s); if (sc->unit_attention_reported) { sc->unit_attention_reported(s); } } /* Create a scsi bus, and attach devices to it. */ void scsi_bus_new(SCSIBus *bus, size_t bus_size, DeviceState *host, const SCSIBusInfo *info, const char *bus_name) { qbus_create_inplace(bus, bus_size, TYPE_SCSI_BUS, host, bus_name); bus->busnr = next_scsi_bus++; bus->info = info; qbus_set_bus_hotplug_handler(BUS(bus), &error_abort); } static void scsi_dma_restart_bh(void *opaque) { SCSIDevice *s = opaque; SCSIRequest *req, *next; qemu_bh_delete(s->bh); s->bh = NULL; QTAILQ_FOREACH_SAFE(req, &s->requests, next, next) { scsi_req_ref(req); if (req->retry) { req->retry = false; switch (req->cmd.mode) { case SCSI_XFER_FROM_DEV: case SCSI_XFER_TO_DEV: scsi_req_continue(req); break; case SCSI_XFER_NONE: scsi_req_dequeue(req); scsi_req_enqueue(req); break; } } scsi_req_unref(req); } } void scsi_req_retry(SCSIRequest *req) { /* No need to save a reference, because scsi_dma_restart_bh just * looks at the request list. */ req->retry = true; } static void scsi_dma_restart_cb(void *opaque, int running, RunState state) { SCSIDevice *s = opaque; if (!running) { return; } if (!s->bh) { AioContext *ctx = blk_get_aio_context(s->conf.blk); s->bh = aio_bh_new(ctx, scsi_dma_restart_bh, s); qemu_bh_schedule(s->bh); } } static void scsi_qdev_realize(DeviceState *qdev, Error **errp) { SCSIDevice *dev = SCSI_DEVICE(qdev); SCSIBus *bus = DO_UPCAST(SCSIBus, qbus, dev->qdev.parent_bus); SCSIDevice *d; Error *local_err = NULL; if (dev->channel > bus->info->max_channel) { error_setg(errp, "bad scsi channel id: %d", dev->channel); return; } if (dev->id != -1 && dev->id > bus->info->max_target) { error_setg(errp, "bad scsi device id: %d", dev->id); return; } if (dev->lun != -1 && dev->lun > bus->info->max_lun) { error_setg(errp, "bad scsi device lun: %d", dev->lun); return; } if (dev->id == -1) { int id = -1; if (dev->lun == -1) { dev->lun = 0; } do { d = scsi_device_find(bus, dev->channel, ++id, dev->lun); } while (d && d->lun == dev->lun && id < bus->info->max_target); if (d && d->lun == dev->lun) { error_setg(errp, "no free target"); return; } dev->id = id; } else if (dev->lun == -1) { int lun = -1; do { d = scsi_device_find(bus, dev->channel, dev->id, ++lun); } while (d && d->lun == lun && lun < bus->info->max_lun); if (d && d->lun == lun) { error_setg(errp, "no free lun"); return; } dev->lun = lun; } else { d = scsi_device_find(bus, dev->channel, dev->id, dev->lun); assert(d); if (d->lun == dev->lun && dev != d) { error_setg(errp, "lun already used by '%s'", d->qdev.id); return; } } QTAILQ_INIT(&dev->requests); scsi_device_realize(dev, &local_err); if (local_err) { error_propagate(errp, local_err); return; } dev->vmsentry = qemu_add_vm_change_state_handler(scsi_dma_restart_cb, dev); } static void scsi_qdev_unrealize(DeviceState *qdev, Error **errp) { SCSIDevice *dev = SCSI_DEVICE(qdev); if (dev->vmsentry) { qemu_del_vm_change_state_handler(dev->vmsentry); } scsi_device_purge_requests(dev, SENSE_CODE(NO_SENSE)); blockdev_mark_auto_del(dev->conf.blk); } /* handle legacy '-drive if=scsi,...' cmd line args */ SCSIDevice *scsi_bus_legacy_add_drive(SCSIBus *bus, BlockBackend *blk, int unit, bool removable, int bootindex, const char *serial, Error **errp) { const char *driver; char *name; DeviceState *dev; Error *err = NULL; driver = blk_is_sg(blk) ? "scsi-generic" : "scsi-disk"; dev = qdev_create(&bus->qbus, driver); name = g_strdup_printf("legacy[%d]", unit); object_property_add_child(OBJECT(bus), name, OBJECT(dev), NULL); g_free(name); qdev_prop_set_uint32(dev, "scsi-id", unit); if (bootindex >= 0) { object_property_set_int(OBJECT(dev), bootindex, "bootindex", &error_abort); } if (object_property_find(OBJECT(dev), "removable", NULL)) { qdev_prop_set_bit(dev, "removable", removable); } if (serial && object_property_find(OBJECT(dev), "serial", NULL)) { qdev_prop_set_string(dev, "serial", serial); } qdev_prop_set_drive(dev, "drive", blk, &err); if (err) { error_propagate(errp, err); object_unparent(OBJECT(dev)); return NULL; } object_property_set_bool(OBJECT(dev), true, "realized", &err); if (err != NULL) { error_propagate(errp, err); object_unparent(OBJECT(dev)); return NULL; } return SCSI_DEVICE(dev); } void scsi_bus_legacy_handle_cmdline(SCSIBus *bus, Error **errp) { Location loc; DriveInfo *dinfo; int unit; Error *err = NULL; loc_push_none(&loc); for (unit = 0; unit <= bus->info->max_target; unit++) { dinfo = drive_get(IF_SCSI, bus->busnr, unit); if (dinfo == NULL) { continue; } qemu_opts_loc_restore(dinfo->opts); scsi_bus_legacy_add_drive(bus, blk_by_legacy_dinfo(dinfo), unit, false, -1, NULL, &err); if (err != NULL) { error_propagate(errp, err); break; } } loc_pop(&loc); } static int32_t scsi_invalid_field(SCSIRequest *req, uint8_t *buf) { scsi_req_build_sense(req, SENSE_CODE(INVALID_FIELD)); scsi_req_complete(req, CHECK_CONDITION); return 0; } static const struct SCSIReqOps reqops_invalid_field = { .size = sizeof(SCSIRequest), .send_command = scsi_invalid_field }; /* SCSIReqOps implementation for invalid commands. */ static int32_t scsi_invalid_command(SCSIRequest *req, uint8_t *buf) { scsi_req_build_sense(req, SENSE_CODE(INVALID_OPCODE)); scsi_req_complete(req, CHECK_CONDITION); return 0; } static const struct SCSIReqOps reqops_invalid_opcode = { .size = sizeof(SCSIRequest), .send_command = scsi_invalid_command }; /* SCSIReqOps implementation for unit attention conditions. */ static int32_t scsi_unit_attention(SCSIRequest *req, uint8_t *buf) { if (req->dev->unit_attention.key == UNIT_ATTENTION) { scsi_req_build_sense(req, req->dev->unit_attention); } else if (req->bus->unit_attention.key == UNIT_ATTENTION) { scsi_req_build_sense(req, req->bus->unit_attention); } scsi_req_complete(req, CHECK_CONDITION); return 0; } static const struct SCSIReqOps reqops_unit_attention = { .size = sizeof(SCSIRequest), .send_command = scsi_unit_attention }; /* SCSIReqOps implementation for REPORT LUNS and for commands sent to an invalid LUN. */ typedef struct SCSITargetReq SCSITargetReq; struct SCSITargetReq { SCSIRequest req; int len; uint8_t *buf; int buf_len; }; static void store_lun(uint8_t *outbuf, int lun) { if (lun < 256) { outbuf[1] = lun; return; } outbuf[1] = (lun & 255); outbuf[0] = (lun >> 8) | 0x40; } static bool scsi_target_emulate_report_luns(SCSITargetReq *r) { BusChild *kid; int i, len, n; int channel, id; bool found_lun0; if (r->req.cmd.xfer < 16) { return false; } if (r->req.cmd.buf[2] > 2) { return false; } channel = r->req.dev->channel; id = r->req.dev->id; found_lun0 = false; n = 0; QTAILQ_FOREACH(kid, &r->req.bus->qbus.children, sibling) { DeviceState *qdev = kid->child; SCSIDevice *dev = SCSI_DEVICE(qdev); if (dev->channel == channel && dev->id == id) { if (dev->lun == 0) { found_lun0 = true; } n += 8; } } if (!found_lun0) { n += 8; } scsi_target_alloc_buf(&r->req, n + 8); len = MIN(n + 8, r->req.cmd.xfer & ~7); memset(r->buf, 0, len); stl_be_p(&r->buf[0], n); i = found_lun0 ? 8 : 16; QTAILQ_FOREACH(kid, &r->req.bus->qbus.children, sibling) { DeviceState *qdev = kid->child; SCSIDevice *dev = SCSI_DEVICE(qdev); if (dev->channel == channel && dev->id == id) { store_lun(&r->buf[i], dev->lun); i += 8; } } assert(i == n + 8); r->len = len; return true; } static bool scsi_target_emulate_inquiry(SCSITargetReq *r) { assert(r->req.dev->lun != r->req.lun); scsi_target_alloc_buf(&r->req, SCSI_INQUIRY_LEN); if (r->req.cmd.buf[1] & 0x2) { /* Command support data - optional, not implemented */ return false; } if (r->req.cmd.buf[1] & 0x1) { /* Vital product data */ uint8_t page_code = r->req.cmd.buf[2]; r->buf[r->len++] = page_code ; /* this page */ r->buf[r->len++] = 0x00; switch (page_code) { case 0x00: /* Supported page codes, mandatory */ { int pages; pages = r->len++; r->buf[r->len++] = 0x00; /* list of supported pages (this page) */ r->buf[pages] = r->len - pages - 1; /* number of pages */ break; } default: return false; } /* done with EVPD */ assert(r->len < r->buf_len); r->len = MIN(r->req.cmd.xfer, r->len); return true; } /* Standard INQUIRY data */ if (r->req.cmd.buf[2] != 0) { return false; } /* PAGE CODE == 0 */ r->len = MIN(r->req.cmd.xfer, SCSI_INQUIRY_LEN); memset(r->buf, 0, r->len); if (r->req.lun != 0) { r->buf[0] = TYPE_NO_LUN; } else { r->buf[0] = TYPE_NOT_PRESENT | TYPE_INACTIVE; r->buf[2] = 5; /* Version */ r->buf[3] = 2 | 0x10; /* HiSup, response data format */ r->buf[4] = r->len - 5; /* Additional Length = (Len - 1) - 4 */ r->buf[7] = 0x10 | (r->req.bus->info->tcq ? 0x02 : 0); /* Sync, TCQ. */ memcpy(&r->buf[8], "QEMU ", 8); memcpy(&r->buf[16], "QEMU TARGET ", 16); pstrcpy((char *) &r->buf[32], 4, qemu_hw_version()); } return true; } static int32_t scsi_target_send_command(SCSIRequest *req, uint8_t *buf) { SCSITargetReq *r = DO_UPCAST(SCSITargetReq, req, req); switch (buf[0]) { case REPORT_LUNS: if (!scsi_target_emulate_report_luns(r)) { goto illegal_request; } break; case INQUIRY: if (!scsi_target_emulate_inquiry(r)) { goto illegal_request; } break; case REQUEST_SENSE: scsi_target_alloc_buf(&r->req, SCSI_SENSE_LEN); r->len = scsi_device_get_sense(r->req.dev, r->buf, MIN(req->cmd.xfer, r->buf_len), (req->cmd.buf[1] & 1) == 0); if (r->req.dev->sense_is_ua) { scsi_device_unit_attention_reported(req->dev); r->req.dev->sense_len = 0; r->req.dev->sense_is_ua = false; } break; case TEST_UNIT_READY: break; default: scsi_req_build_sense(req, SENSE_CODE(LUN_NOT_SUPPORTED)); scsi_req_complete(req, CHECK_CONDITION); return 0; illegal_request: scsi_req_build_sense(req, SENSE_CODE(INVALID_FIELD)); scsi_req_complete(req, CHECK_CONDITION); return 0; } if (!r->len) { scsi_req_complete(req, GOOD); } return r->len; } static void scsi_target_read_data(SCSIRequest *req) { SCSITargetReq *r = DO_UPCAST(SCSITargetReq, req, req); uint32_t n; n = r->len; if (n > 0) { r->len = 0; scsi_req_data(&r->req, n); } else { scsi_req_complete(&r->req, GOOD); } } static uint8_t *scsi_target_get_buf(SCSIRequest *req) { SCSITargetReq *r = DO_UPCAST(SCSITargetReq, req, req); return r->buf; } static uint8_t *scsi_target_alloc_buf(SCSIRequest *req, size_t len) { SCSITargetReq *r = DO_UPCAST(SCSITargetReq, req, req); r->buf = g_malloc(len); r->buf_len = len; return r->buf; } static void scsi_target_free_buf(SCSIRequest *req) { SCSITargetReq *r = DO_UPCAST(SCSITargetReq, req, req); g_free(r->buf); } static const struct SCSIReqOps reqops_target_command = { .size = sizeof(SCSITargetReq), .send_command = scsi_target_send_command, .read_data = scsi_target_read_data, .get_buf = scsi_target_get_buf, .free_req = scsi_target_free_buf, }; SCSIRequest *scsi_req_alloc(const SCSIReqOps *reqops, SCSIDevice *d, uint32_t tag, uint32_t lun, void *hba_private) { SCSIRequest *req; SCSIBus *bus = scsi_bus_from_device(d); BusState *qbus = BUS(bus); const int memset_off = offsetof(SCSIRequest, sense) + sizeof(req->sense); req = g_malloc(reqops->size); memset((uint8_t *)req + memset_off, 0, reqops->size - memset_off); req->refcount = 1; req->bus = bus; req->dev = d; req->tag = tag; req->lun = lun; req->hba_private = hba_private; req->status = -1; req->ops = reqops; object_ref(OBJECT(d)); object_ref(OBJECT(qbus->parent)); notifier_list_init(&req->cancel_notifiers); trace_scsi_req_alloc(req->dev->id, req->lun, req->tag); return req; } SCSIRequest *scsi_req_new(SCSIDevice *d, uint32_t tag, uint32_t lun, uint8_t *buf, void *hba_private) { SCSIBus *bus = DO_UPCAST(SCSIBus, qbus, d->qdev.parent_bus); const SCSIReqOps *ops; SCSIDeviceClass *sc = SCSI_DEVICE_GET_CLASS(d); SCSIRequest *req; SCSICommand cmd = { .len = 0 }; int ret; if ((d->unit_attention.key == UNIT_ATTENTION || bus->unit_attention.key == UNIT_ATTENTION) && (buf[0] != INQUIRY && buf[0] != REPORT_LUNS && buf[0] != GET_CONFIGURATION && buf[0] != GET_EVENT_STATUS_NOTIFICATION && /* * If we already have a pending unit attention condition, * report this one before triggering another one. */ !(buf[0] == REQUEST_SENSE && d->sense_is_ua))) { ops = &reqops_unit_attention; } else if (lun != d->lun || buf[0] == REPORT_LUNS || (buf[0] == REQUEST_SENSE && d->sense_len)) { ops = &reqops_target_command; } else { ops = NULL; } if (ops != NULL || !sc->parse_cdb) { ret = scsi_req_parse_cdb(d, &cmd, buf); } else { ret = sc->parse_cdb(d, &cmd, buf, hba_private); } if (ret != 0) { trace_scsi_req_parse_bad(d->id, lun, tag, buf[0]); req = scsi_req_alloc(&reqops_invalid_opcode, d, tag, lun, hba_private); } else { assert(cmd.len != 0); trace_scsi_req_parsed(d->id, lun, tag, buf[0], cmd.mode, cmd.xfer); if (cmd.lba != -1) { trace_scsi_req_parsed_lba(d->id, lun, tag, buf[0], cmd.lba); } if (cmd.xfer > INT32_MAX) { req = scsi_req_alloc(&reqops_invalid_field, d, tag, lun, hba_private); } else if (ops) { req = scsi_req_alloc(ops, d, tag, lun, hba_private); } else { req = scsi_device_alloc_req(d, tag, lun, buf, hba_private); } } req->cmd = cmd; req->resid = req->cmd.xfer; switch (buf[0]) { case INQUIRY: trace_scsi_inquiry(d->id, lun, tag, cmd.buf[1], cmd.buf[2]); break; case TEST_UNIT_READY: trace_scsi_test_unit_ready(d->id, lun, tag); break; case REPORT_LUNS: trace_scsi_report_luns(d->id, lun, tag); break; case REQUEST_SENSE: trace_scsi_request_sense(d->id, lun, tag); break; default: break; } return req; } uint8_t *scsi_req_get_buf(SCSIRequest *req) { return req->ops->get_buf(req); } static void scsi_clear_unit_attention(SCSIRequest *req) { SCSISense *ua; if (req->dev->unit_attention.key != UNIT_ATTENTION && req->bus->unit_attention.key != UNIT_ATTENTION) { return; } /* * If an INQUIRY command enters the enabled command state, * the device server shall [not] clear any unit attention condition; * See also MMC-6, paragraphs 6.5 and 6.6.2. */ if (req->cmd.buf[0] == INQUIRY || req->cmd.buf[0] == GET_CONFIGURATION || req->cmd.buf[0] == GET_EVENT_STATUS_NOTIFICATION) { return; } if (req->dev->unit_attention.key == UNIT_ATTENTION) { ua = &req->dev->unit_attention; } else { ua = &req->bus->unit_attention; } /* * If a REPORT LUNS command enters the enabled command state, [...] * the device server shall clear any pending unit attention condition * with an additional sense code of REPORTED LUNS DATA HAS CHANGED. */ if (req->cmd.buf[0] == REPORT_LUNS && !(ua->asc == SENSE_CODE(REPORTED_LUNS_CHANGED).asc && ua->ascq == SENSE_CODE(REPORTED_LUNS_CHANGED).ascq)) { return; } *ua = SENSE_CODE(NO_SENSE); } int scsi_req_get_sense(SCSIRequest *req, uint8_t *buf, int len) { int ret; assert(len >= 14); if (!req->sense_len) { return 0; } ret = scsi_build_sense(req->sense, req->sense_len, buf, len, true); /* * FIXME: clearing unit attention conditions upon autosense should be done * only if the UA_INTLCK_CTRL field in the Control mode page is set to 00b * (SAM-5, 5.14). * * We assume UA_INTLCK_CTRL to be 00b for HBAs that support autosense, and * 10b for HBAs that do not support it (do not call scsi_req_get_sense). * Here we handle unit attention clearing for UA_INTLCK_CTRL == 00b. */ if (req->dev->sense_is_ua) { scsi_device_unit_attention_reported(req->dev); req->dev->sense_len = 0; req->dev->sense_is_ua = false; } return ret; } int scsi_device_get_sense(SCSIDevice *dev, uint8_t *buf, int len, bool fixed) { return scsi_build_sense(dev->sense, dev->sense_len, buf, len, fixed); } void scsi_req_build_sense(SCSIRequest *req, SCSISense sense) { trace_scsi_req_build_sense(req->dev->id, req->lun, req->tag, sense.key, sense.asc, sense.ascq); memset(req->sense, 0, 18); req->sense[0] = 0x70; req->sense[2] = sense.key; req->sense[7] = 10; req->sense[12] = sense.asc; req->sense[13] = sense.ascq; req->sense_len = 18; } static void scsi_req_enqueue_internal(SCSIRequest *req) { assert(!req->enqueued); scsi_req_ref(req); if (req->bus->info->get_sg_list) { req->sg = req->bus->info->get_sg_list(req); } else { req->sg = NULL; } req->enqueued = true; QTAILQ_INSERT_TAIL(&req->dev->requests, req, next); } int32_t scsi_req_enqueue(SCSIRequest *req) { int32_t rc; assert(!req->retry); scsi_req_enqueue_internal(req); scsi_req_ref(req); rc = req->ops->send_command(req, req->cmd.buf); scsi_req_unref(req); return rc; } static void scsi_req_dequeue(SCSIRequest *req) { trace_scsi_req_dequeue(req->dev->id, req->lun, req->tag); req->retry = false; if (req->enqueued) { QTAILQ_REMOVE(&req->dev->requests, req, next); req->enqueued = false; scsi_req_unref(req); } } static int scsi_get_performance_length(int num_desc, int type, int data_type) { /* MMC-6, paragraph 6.7. */ switch (type) { case 0: if ((data_type & 3) == 0) { /* Each descriptor is as in Table 295 - Nominal performance. */ return 16 * num_desc + 8; } else { /* Each descriptor is as in Table 296 - Exceptions. */ return 6 * num_desc + 8; } case 1: case 4: case 5: return 8 * num_desc + 8; case 2: return 2048 * num_desc + 8; case 3: return 16 * num_desc + 8; default: return 8; } } static int ata_passthrough_xfer_unit(SCSIDevice *dev, uint8_t *buf) { int byte_block = (buf[2] >> 2) & 0x1; int type = (buf[2] >> 4) & 0x1; int xfer_unit; if (byte_block) { if (type) { xfer_unit = dev->blocksize; } else { xfer_unit = 512; } } else { xfer_unit = 1; } return xfer_unit; } static int ata_passthrough_12_xfer(SCSIDevice *dev, uint8_t *buf) { int length = buf[2] & 0x3; int xfer; int unit = ata_passthrough_xfer_unit(dev, buf); switch (length) { case 0: case 3: /* USB-specific. */ default: xfer = 0; break; case 1: xfer = buf[3]; break; case 2: xfer = buf[4]; break; } return xfer * unit; } static int ata_passthrough_16_xfer(SCSIDevice *dev, uint8_t *buf) { int extend = buf[1] & 0x1; int length = buf[2] & 0x3; int xfer; int unit = ata_passthrough_xfer_unit(dev, buf); switch (length) { case 0: case 3: /* USB-specific. */ default: xfer = 0; break; case 1: xfer = buf[4]; xfer |= (extend ? buf[3] << 8 : 0); break; case 2: xfer = buf[6]; xfer |= (extend ? buf[5] << 8 : 0); break; } return xfer * unit; } uint32_t scsi_data_cdb_xfer(uint8_t *buf) { if ((buf[0] >> 5) == 0 && buf[4] == 0) { return 256; } else { return scsi_cdb_xfer(buf); } } uint32_t scsi_cdb_xfer(uint8_t *buf) { switch (buf[0] >> 5) { case 0: return buf[4]; break; case 1: case 2: return lduw_be_p(&buf[7]); break; case 4: return ldl_be_p(&buf[10]) & 0xffffffffULL; break; case 5: return ldl_be_p(&buf[6]) & 0xffffffffULL; break; default: return -1; } } static int scsi_req_xfer(SCSICommand *cmd, SCSIDevice *dev, uint8_t *buf) { cmd->xfer = scsi_cdb_xfer(buf); switch (buf[0]) { case TEST_UNIT_READY: case REWIND: case START_STOP: case SET_CAPACITY: case WRITE_FILEMARKS: case WRITE_FILEMARKS_16: case SPACE: case RESERVE: case RELEASE: case ERASE: case ALLOW_MEDIUM_REMOVAL: case SEEK_10: case SYNCHRONIZE_CACHE: case SYNCHRONIZE_CACHE_16: case LOCATE_16: case LOCK_UNLOCK_CACHE: case SET_CD_SPEED: case SET_LIMITS: case WRITE_LONG_10: case UPDATE_BLOCK: case RESERVE_TRACK: case SET_READ_AHEAD: case PRE_FETCH: case PRE_FETCH_16: case ALLOW_OVERWRITE: cmd->xfer = 0; break; case VERIFY_10: case VERIFY_12: case VERIFY_16: if ((buf[1] & 2) == 0) { cmd->xfer = 0; } else if ((buf[1] & 4) != 0) { cmd->xfer = 1; } cmd->xfer *= dev->blocksize; break; case MODE_SENSE: break; case WRITE_SAME_10: case WRITE_SAME_16: cmd->xfer = dev->blocksize; break; case READ_CAPACITY_10: cmd->xfer = 8; break; case READ_BLOCK_LIMITS: cmd->xfer = 6; break; case SEND_VOLUME_TAG: /* GPCMD_SET_STREAMING from multimedia commands. */ if (dev->type == TYPE_ROM) { cmd->xfer = buf[10] | (buf[9] << 8); } else { cmd->xfer = buf[9] | (buf[8] << 8); } break; case WRITE_6: /* length 0 means 256 blocks */ if (cmd->xfer == 0) { cmd->xfer = 256; } /* fall through */ case WRITE_10: case WRITE_VERIFY_10: case WRITE_12: case WRITE_VERIFY_12: case WRITE_16: case WRITE_VERIFY_16: cmd->xfer *= dev->blocksize; break; case READ_6: case READ_REVERSE: /* length 0 means 256 blocks */ if (cmd->xfer == 0) { cmd->xfer = 256; } /* fall through */ case READ_10: case READ_12: case READ_16: cmd->xfer *= dev->blocksize; break; case FORMAT_UNIT: /* MMC mandates the parameter list to be 12-bytes long. Parameters * for block devices are restricted to the header right now. */ if (dev->type == TYPE_ROM && (buf[1] & 16)) { cmd->xfer = 12; } else { cmd->xfer = (buf[1] & 16) == 0 ? 0 : (buf[1] & 32 ? 8 : 4); } break; case INQUIRY: case RECEIVE_DIAGNOSTIC: case SEND_DIAGNOSTIC: cmd->xfer = buf[4] | (buf[3] << 8); break; case READ_CD: case READ_BUFFER: case WRITE_BUFFER: case SEND_CUE_SHEET: cmd->xfer = buf[8] | (buf[7] << 8) | (buf[6] << 16); break; case PERSISTENT_RESERVE_OUT: cmd->xfer = ldl_be_p(&buf[5]) & 0xffffffffULL; break; case ERASE_12: if (dev->type == TYPE_ROM) { /* MMC command GET PERFORMANCE. */ cmd->xfer = scsi_get_performance_length(buf[9] | (buf[8] << 8), buf[10], buf[1] & 0x1f); } break; case MECHANISM_STATUS: case READ_DVD_STRUCTURE: case SEND_DVD_STRUCTURE: case MAINTENANCE_OUT: case MAINTENANCE_IN: if (dev->type == TYPE_ROM) { /* GPCMD_REPORT_KEY and GPCMD_SEND_KEY from multi media commands */ cmd->xfer = buf[9] | (buf[8] << 8); } break; case ATA_PASSTHROUGH_12: if (dev->type == TYPE_ROM) { /* BLANK command of MMC */ cmd->xfer = 0; } else { cmd->xfer = ata_passthrough_12_xfer(dev, buf); } break; case ATA_PASSTHROUGH_16: cmd->xfer = ata_passthrough_16_xfer(dev, buf); break; } return 0; } static int scsi_req_stream_xfer(SCSICommand *cmd, SCSIDevice *dev, uint8_t *buf) { switch (buf[0]) { /* stream commands */ case ERASE_12: case ERASE_16: cmd->xfer = 0; break; case READ_6: case READ_REVERSE: case RECOVER_BUFFERED_DATA: case WRITE_6: cmd->xfer = buf[4] | (buf[3] << 8) | (buf[2] << 16); if (buf[1] & 0x01) { /* fixed */ cmd->xfer *= dev->blocksize; } break; case READ_16: case READ_REVERSE_16: case VERIFY_16: case WRITE_16: cmd->xfer = buf[14] | (buf[13] << 8) | (buf[12] << 16); if (buf[1] & 0x01) { /* fixed */ cmd->xfer *= dev->blocksize; } break; case REWIND: case LOAD_UNLOAD: cmd->xfer = 0; break; case SPACE_16: cmd->xfer = buf[13] | (buf[12] << 8); break; case READ_POSITION: switch (buf[1] & 0x1f) /* operation code */ { case SHORT_FORM_BLOCK_ID: case SHORT_FORM_VENDOR_SPECIFIC: cmd->xfer = 20; break; case LONG_FORM: cmd->xfer = 32; break; case EXTENDED_FORM: cmd->xfer = buf[8] | (buf[7] << 8); break; default: return -1; } break; case FORMAT_UNIT: cmd->xfer = buf[4] | (buf[3] << 8); break; /* generic commands */ default: return scsi_req_xfer(cmd, dev, buf); } return 0; } static int scsi_req_medium_changer_xfer(SCSICommand *cmd, SCSIDevice *dev, uint8_t *buf) { switch (buf[0]) { /* medium changer commands */ case EXCHANGE_MEDIUM: case INITIALIZE_ELEMENT_STATUS: case INITIALIZE_ELEMENT_STATUS_WITH_RANGE: case MOVE_MEDIUM: case POSITION_TO_ELEMENT: cmd->xfer = 0; break; case READ_ELEMENT_STATUS: cmd->xfer = buf[9] | (buf[8] << 8) | (buf[7] << 16); break; /* generic commands */ default: return scsi_req_xfer(cmd, dev, buf); } return 0; } static int scsi_req_scanner_length(SCSICommand *cmd, SCSIDevice *dev, uint8_t *buf) { switch (buf[0]) { /* Scanner commands */ case OBJECT_POSITION: cmd->xfer = 0; break; case SCAN: cmd->xfer = buf[4]; break; case READ_10: case SEND: case GET_WINDOW: case SET_WINDOW: cmd->xfer = buf[8] | (buf[7] << 8) | (buf[6] << 16); break; default: /* GET_DATA_BUFFER_STATUS xfer handled by scsi_req_xfer */ return scsi_req_xfer(cmd, dev, buf); } return 0; } static void scsi_cmd_xfer_mode(SCSICommand *cmd) { if (!cmd->xfer) { cmd->mode = SCSI_XFER_NONE; return; } switch (cmd->buf[0]) { case WRITE_6: case WRITE_10: case WRITE_VERIFY_10: case WRITE_12: case WRITE_VERIFY_12: case WRITE_16: case WRITE_VERIFY_16: case VERIFY_10: case VERIFY_12: case VERIFY_16: case COPY: case COPY_VERIFY: case COMPARE: case CHANGE_DEFINITION: case LOG_SELECT: case MODE_SELECT: case MODE_SELECT_10: case SEND_DIAGNOSTIC: case WRITE_BUFFER: case FORMAT_UNIT: case REASSIGN_BLOCKS: case SEARCH_EQUAL: case SEARCH_HIGH: case SEARCH_LOW: case UPDATE_BLOCK: case WRITE_LONG_10: case WRITE_SAME_10: case WRITE_SAME_16: case UNMAP: case SEARCH_HIGH_12: case SEARCH_EQUAL_12: case SEARCH_LOW_12: case MEDIUM_SCAN: case SEND_VOLUME_TAG: case SEND_CUE_SHEET: case SEND_DVD_STRUCTURE: case PERSISTENT_RESERVE_OUT: case MAINTENANCE_OUT: case SET_WINDOW: case SCAN: /* SCAN conflicts with START_STOP. START_STOP has cmd->xfer set to 0 for * non-scanner devices, so we only get here for SCAN and not for START_STOP. */ cmd->mode = SCSI_XFER_TO_DEV; break; case ATA_PASSTHROUGH_12: case ATA_PASSTHROUGH_16: /* T_DIR */ cmd->mode = (cmd->buf[2] & 0x8) ? SCSI_XFER_FROM_DEV : SCSI_XFER_TO_DEV; break; default: cmd->mode = SCSI_XFER_FROM_DEV; break; } } static uint64_t scsi_cmd_lba(SCSICommand *cmd) { uint8_t *buf = cmd->buf; uint64_t lba; switch (buf[0] >> 5) { case 0: lba = ldl_be_p(&buf[0]) & 0x1fffff; break; case 1: case 2: case 5: lba = ldl_be_p(&buf[2]) & 0xffffffffULL; break; case 4: lba = ldq_be_p(&buf[2]); break; default: lba = -1; } return lba; } int scsi_cdb_length(uint8_t *buf) { int cdb_len; switch (buf[0] >> 5) { case 0: cdb_len = 6; break; case 1: case 2: cdb_len = 10; break; case 4: cdb_len = 16; break; case 5: cdb_len = 12; break; default: cdb_len = -1; } return cdb_len; } int scsi_req_parse_cdb(SCSIDevice *dev, SCSICommand *cmd, uint8_t *buf) { int rc; int len; cmd->lba = -1; len = scsi_cdb_length(buf); if (len < 0) { return -1; } cmd->len = len; switch (dev->type) { case TYPE_TAPE: rc = scsi_req_stream_xfer(cmd, dev, buf); break; case TYPE_MEDIUM_CHANGER: rc = scsi_req_medium_changer_xfer(cmd, dev, buf); break; case TYPE_SCANNER: rc = scsi_req_scanner_length(cmd, dev, buf); break; default: rc = scsi_req_xfer(cmd, dev, buf); break; } if (rc != 0) return rc; memcpy(cmd->buf, buf, cmd->len); scsi_cmd_xfer_mode(cmd); cmd->lba = scsi_cmd_lba(cmd); return 0; } void scsi_device_report_change(SCSIDevice *dev, SCSISense sense) { SCSIBus *bus = DO_UPCAST(SCSIBus, qbus, dev->qdev.parent_bus); scsi_device_set_ua(dev, sense); if (bus->info->change) { bus->info->change(bus, dev, sense); } } /* * Predefined sense codes */ /* No sense data available */ const struct SCSISense sense_code_NO_SENSE = { .key = NO_SENSE , .asc = 0x00 , .ascq = 0x00 }; /* LUN not ready, Manual intervention required */ const struct SCSISense sense_code_LUN_NOT_READY = { .key = NOT_READY, .asc = 0x04, .ascq = 0x03 }; /* LUN not ready, Medium not present */ const struct SCSISense sense_code_NO_MEDIUM = { .key = NOT_READY, .asc = 0x3a, .ascq = 0x00 }; /* LUN not ready, medium removal prevented */ const struct SCSISense sense_code_NOT_READY_REMOVAL_PREVENTED = { .key = NOT_READY, .asc = 0x53, .ascq = 0x02 }; /* Hardware error, internal target failure */ const struct SCSISense sense_code_TARGET_FAILURE = { .key = HARDWARE_ERROR, .asc = 0x44, .ascq = 0x00 }; /* Illegal request, invalid command operation code */ const struct SCSISense sense_code_INVALID_OPCODE = { .key = ILLEGAL_REQUEST, .asc = 0x20, .ascq = 0x00 }; /* Illegal request, LBA out of range */ const struct SCSISense sense_code_LBA_OUT_OF_RANGE = { .key = ILLEGAL_REQUEST, .asc = 0x21, .ascq = 0x00 }; /* Illegal request, Invalid field in CDB */ const struct SCSISense sense_code_INVALID_FIELD = { .key = ILLEGAL_REQUEST, .asc = 0x24, .ascq = 0x00 }; /* Illegal request, Invalid field in parameter list */ const struct SCSISense sense_code_INVALID_PARAM = { .key = ILLEGAL_REQUEST, .asc = 0x26, .ascq = 0x00 }; /* Illegal request, Parameter list length error */ const struct SCSISense sense_code_INVALID_PARAM_LEN = { .key = ILLEGAL_REQUEST, .asc = 0x1a, .ascq = 0x00 }; /* Illegal request, LUN not supported */ const struct SCSISense sense_code_LUN_NOT_SUPPORTED = { .key = ILLEGAL_REQUEST, .asc = 0x25, .ascq = 0x00 }; /* Illegal request, Saving parameters not supported */ const struct SCSISense sense_code_SAVING_PARAMS_NOT_SUPPORTED = { .key = ILLEGAL_REQUEST, .asc = 0x39, .ascq = 0x00 }; /* Illegal request, Incompatible medium installed */ const struct SCSISense sense_code_INCOMPATIBLE_FORMAT = { .key = ILLEGAL_REQUEST, .asc = 0x30, .ascq = 0x00 }; /* Illegal request, medium removal prevented */ const struct SCSISense sense_code_ILLEGAL_REQ_REMOVAL_PREVENTED = { .key = ILLEGAL_REQUEST, .asc = 0x53, .ascq = 0x02 }; /* Illegal request, Invalid Transfer Tag */ const struct SCSISense sense_code_INVALID_TAG = { .key = ILLEGAL_REQUEST, .asc = 0x4b, .ascq = 0x01 }; /* Command aborted, I/O process terminated */ const struct SCSISense sense_code_IO_ERROR = { .key = ABORTED_COMMAND, .asc = 0x00, .ascq = 0x06 }; /* Command aborted, I_T Nexus loss occurred */ const struct SCSISense sense_code_I_T_NEXUS_LOSS = { .key = ABORTED_COMMAND, .asc = 0x29, .ascq = 0x07 }; /* Command aborted, Logical Unit failure */ const struct SCSISense sense_code_LUN_FAILURE = { .key = ABORTED_COMMAND, .asc = 0x3e, .ascq = 0x01 }; /* Command aborted, Overlapped Commands Attempted */ const struct SCSISense sense_code_OVERLAPPED_COMMANDS = { .key = ABORTED_COMMAND, .asc = 0x4e, .ascq = 0x00 }; /* Unit attention, Capacity data has changed */ const struct SCSISense sense_code_CAPACITY_CHANGED = { .key = UNIT_ATTENTION, .asc = 0x2a, .ascq = 0x09 }; /* Unit attention, Power on, reset or bus device reset occurred */ const struct SCSISense sense_code_RESET = { .key = UNIT_ATTENTION, .asc = 0x29, .ascq = 0x00 }; /* Unit attention, No medium */ const struct SCSISense sense_code_UNIT_ATTENTION_NO_MEDIUM = { .key = UNIT_ATTENTION, .asc = 0x3a, .ascq = 0x00 }; /* Unit attention, Medium may have changed */ const struct SCSISense sense_code_MEDIUM_CHANGED = { .key = UNIT_ATTENTION, .asc = 0x28, .ascq = 0x00 }; /* Unit attention, Reported LUNs data has changed */ const struct SCSISense sense_code_REPORTED_LUNS_CHANGED = { .key = UNIT_ATTENTION, .asc = 0x3f, .ascq = 0x0e }; /* Unit attention, Device internal reset */ const struct SCSISense sense_code_DEVICE_INTERNAL_RESET = { .key = UNIT_ATTENTION, .asc = 0x29, .ascq = 0x04 }; /* Data Protection, Write Protected */ const struct SCSISense sense_code_WRITE_PROTECTED = { .key = DATA_PROTECT, .asc = 0x27, .ascq = 0x00 }; /* Data Protection, Space Allocation Failed Write Protect */ const struct SCSISense sense_code_SPACE_ALLOC_FAILED = { .key = DATA_PROTECT, .asc = 0x27, .ascq = 0x07 }; /* * scsi_build_sense * * Convert between fixed and descriptor sense buffers */ int scsi_build_sense(uint8_t *in_buf, int in_len, uint8_t *buf, int len, bool fixed) { bool fixed_in; SCSISense sense; if (!fixed && len < 8) { return 0; } if (in_len == 0) { sense.key = NO_SENSE; sense.asc = 0; sense.ascq = 0; } else { fixed_in = (in_buf[0] & 2) == 0; if (fixed == fixed_in) { memcpy(buf, in_buf, MIN(len, in_len)); return MIN(len, in_len); } if (fixed_in) { sense.key = in_buf[2]; sense.asc = in_buf[12]; sense.ascq = in_buf[13]; } else { sense.key = in_buf[1]; sense.asc = in_buf[2]; sense.ascq = in_buf[3]; } } memset(buf, 0, len); if (fixed) { /* Return fixed format sense buffer */ buf[0] = 0x70; buf[2] = sense.key; buf[7] = 10; buf[12] = sense.asc; buf[13] = sense.ascq; return MIN(len, SCSI_SENSE_LEN); } else { /* Return descriptor format sense buffer */ buf[0] = 0x72; buf[1] = sense.key; buf[2] = sense.asc; buf[3] = sense.ascq; return 8; } } const char *scsi_command_name(uint8_t cmd) { static const char *names[] = { [ TEST_UNIT_READY ] = "TEST_UNIT_READY", [ REWIND ] = "REWIND", [ REQUEST_SENSE ] = "REQUEST_SENSE", [ FORMAT_UNIT ] = "FORMAT_UNIT", [ READ_BLOCK_LIMITS ] = "READ_BLOCK_LIMITS", [ REASSIGN_BLOCKS ] = "REASSIGN_BLOCKS/INITIALIZE ELEMENT STATUS", /* LOAD_UNLOAD and INITIALIZE_ELEMENT_STATUS use the same operation code */ [ READ_6 ] = "READ_6", [ WRITE_6 ] = "WRITE_6", [ SET_CAPACITY ] = "SET_CAPACITY", [ READ_REVERSE ] = "READ_REVERSE", [ WRITE_FILEMARKS ] = "WRITE_FILEMARKS", [ SPACE ] = "SPACE", [ INQUIRY ] = "INQUIRY", [ RECOVER_BUFFERED_DATA ] = "RECOVER_BUFFERED_DATA", [ MAINTENANCE_IN ] = "MAINTENANCE_IN", [ MAINTENANCE_OUT ] = "MAINTENANCE_OUT", [ MODE_SELECT ] = "MODE_SELECT", [ RESERVE ] = "RESERVE", [ RELEASE ] = "RELEASE", [ COPY ] = "COPY", [ ERASE ] = "ERASE", [ MODE_SENSE ] = "MODE_SENSE", [ START_STOP ] = "START_STOP/LOAD_UNLOAD", /* LOAD_UNLOAD and START_STOP use the same operation code */ [ RECEIVE_DIAGNOSTIC ] = "RECEIVE_DIAGNOSTIC", [ SEND_DIAGNOSTIC ] = "SEND_DIAGNOSTIC", [ ALLOW_MEDIUM_REMOVAL ] = "ALLOW_MEDIUM_REMOVAL", [ READ_CAPACITY_10 ] = "READ_CAPACITY_10", [ READ_10 ] = "READ_10", [ WRITE_10 ] = "WRITE_10", [ SEEK_10 ] = "SEEK_10/POSITION_TO_ELEMENT", /* SEEK_10 and POSITION_TO_ELEMENT use the same operation code */ [ WRITE_VERIFY_10 ] = "WRITE_VERIFY_10", [ VERIFY_10 ] = "VERIFY_10", [ SEARCH_HIGH ] = "SEARCH_HIGH", [ SEARCH_EQUAL ] = "SEARCH_EQUAL", [ SEARCH_LOW ] = "SEARCH_LOW", [ SET_LIMITS ] = "SET_LIMITS", [ PRE_FETCH ] = "PRE_FETCH/READ_POSITION", /* READ_POSITION and PRE_FETCH use the same operation code */ [ SYNCHRONIZE_CACHE ] = "SYNCHRONIZE_CACHE", [ LOCK_UNLOCK_CACHE ] = "LOCK_UNLOCK_CACHE", [ READ_DEFECT_DATA ] = "READ_DEFECT_DATA/INITIALIZE_ELEMENT_STATUS_WITH_RANGE", /* READ_DEFECT_DATA and INITIALIZE_ELEMENT_STATUS_WITH_RANGE use the same operation code */ [ MEDIUM_SCAN ] = "MEDIUM_SCAN", [ COMPARE ] = "COMPARE", [ COPY_VERIFY ] = "COPY_VERIFY", [ WRITE_BUFFER ] = "WRITE_BUFFER", [ READ_BUFFER ] = "READ_BUFFER", [ UPDATE_BLOCK ] = "UPDATE_BLOCK", [ READ_LONG_10 ] = "READ_LONG_10", [ WRITE_LONG_10 ] = "WRITE_LONG_10", [ CHANGE_DEFINITION ] = "CHANGE_DEFINITION", [ WRITE_SAME_10 ] = "WRITE_SAME_10", [ UNMAP ] = "UNMAP", [ READ_TOC ] = "READ_TOC", [ REPORT_DENSITY_SUPPORT ] = "REPORT_DENSITY_SUPPORT", [ SANITIZE ] = "SANITIZE", [ GET_CONFIGURATION ] = "GET_CONFIGURATION", [ LOG_SELECT ] = "LOG_SELECT", [ LOG_SENSE ] = "LOG_SENSE", [ MODE_SELECT_10 ] = "MODE_SELECT_10", [ RESERVE_10 ] = "RESERVE_10", [ RELEASE_10 ] = "RELEASE_10", [ MODE_SENSE_10 ] = "MODE_SENSE_10", [ PERSISTENT_RESERVE_IN ] = "PERSISTENT_RESERVE_IN", [ PERSISTENT_RESERVE_OUT ] = "PERSISTENT_RESERVE_OUT", [ WRITE_FILEMARKS_16 ] = "WRITE_FILEMARKS_16", [ EXTENDED_COPY ] = "EXTENDED_COPY", [ ATA_PASSTHROUGH_16 ] = "ATA_PASSTHROUGH_16", [ ACCESS_CONTROL_IN ] = "ACCESS_CONTROL_IN", [ ACCESS_CONTROL_OUT ] = "ACCESS_CONTROL_OUT", [ READ_16 ] = "READ_16", [ COMPARE_AND_WRITE ] = "COMPARE_AND_WRITE", [ WRITE_16 ] = "WRITE_16", [ WRITE_VERIFY_16 ] = "WRITE_VERIFY_16", [ VERIFY_16 ] = "VERIFY_16", [ PRE_FETCH_16 ] = "PRE_FETCH_16", [ SYNCHRONIZE_CACHE_16 ] = "SPACE_16/SYNCHRONIZE_CACHE_16", /* SPACE_16 and SYNCHRONIZE_CACHE_16 use the same operation code */ [ LOCATE_16 ] = "LOCATE_16", [ WRITE_SAME_16 ] = "ERASE_16/WRITE_SAME_16", /* ERASE_16 and WRITE_SAME_16 use the same operation code */ [ SERVICE_ACTION_IN_16 ] = "SERVICE_ACTION_IN_16", [ WRITE_LONG_16 ] = "WRITE_LONG_16", [ REPORT_LUNS ] = "REPORT_LUNS", [ ATA_PASSTHROUGH_12 ] = "BLANK/ATA_PASSTHROUGH_12", [ MOVE_MEDIUM ] = "MOVE_MEDIUM", [ EXCHANGE_MEDIUM ] = "EXCHANGE MEDIUM", [ READ_12 ] = "READ_12", [ WRITE_12 ] = "WRITE_12", [ ERASE_12 ] = "ERASE_12/GET_PERFORMANCE", /* ERASE_12 and GET_PERFORMANCE use the same operation code */ [ SERVICE_ACTION_IN_12 ] = "SERVICE_ACTION_IN_12", [ WRITE_VERIFY_12 ] = "WRITE_VERIFY_12", [ VERIFY_12 ] = "VERIFY_12", [ SEARCH_HIGH_12 ] = "SEARCH_HIGH_12", [ SEARCH_EQUAL_12 ] = "SEARCH_EQUAL_12", [ SEARCH_LOW_12 ] = "SEARCH_LOW_12", [ READ_ELEMENT_STATUS ] = "READ_ELEMENT_STATUS", [ SEND_VOLUME_TAG ] = "SEND_VOLUME_TAG/SET_STREAMING", /* SEND_VOLUME_TAG and SET_STREAMING use the same operation code */ [ READ_CD ] = "READ_CD", [ READ_DEFECT_DATA_12 ] = "READ_DEFECT_DATA_12", [ READ_DVD_STRUCTURE ] = "READ_DVD_STRUCTURE", [ RESERVE_TRACK ] = "RESERVE_TRACK", [ SEND_CUE_SHEET ] = "SEND_CUE_SHEET", [ SEND_DVD_STRUCTURE ] = "SEND_DVD_STRUCTURE", [ SET_CD_SPEED ] = "SET_CD_SPEED", [ SET_READ_AHEAD ] = "SET_READ_AHEAD", [ ALLOW_OVERWRITE ] = "ALLOW_OVERWRITE", [ MECHANISM_STATUS ] = "MECHANISM_STATUS", [ GET_EVENT_STATUS_NOTIFICATION ] = "GET_EVENT_STATUS_NOTIFICATION", [ READ_DISC_INFORMATION ] = "READ_DISC_INFORMATION", }; if (cmd >= ARRAY_SIZE(names) || names[cmd] == NULL) return "*UNKNOWN*"; return names[cmd]; } SCSIRequest *scsi_req_ref(SCSIRequest *req) { assert(req->refcount > 0); req->refcount++; return req; } void scsi_req_unref(SCSIRequest *req) { assert(req->refcount > 0); if (--req->refcount == 0) { BusState *qbus = req->dev->qdev.parent_bus; SCSIBus *bus = DO_UPCAST(SCSIBus, qbus, qbus); if (bus->info->free_request && req->hba_private) { bus->info->free_request(bus, req->hba_private); } if (req->ops->free_req) { req->ops->free_req(req); } object_unref(OBJECT(req->dev)); object_unref(OBJECT(qbus->parent)); g_free(req); } } /* Tell the device that we finished processing this chunk of I/O. It will start the next chunk or complete the command. */ void scsi_req_continue(SCSIRequest *req) { if (req->io_canceled) { trace_scsi_req_continue_canceled(req->dev->id, req->lun, req->tag); return; } trace_scsi_req_continue(req->dev->id, req->lun, req->tag); if (req->cmd.mode == SCSI_XFER_TO_DEV) { req->ops->write_data(req); } else { req->ops->read_data(req); } } /* Called by the devices when data is ready for the HBA. The HBA should start a DMA operation to read or fill the device's data buffer. Once it completes, calling scsi_req_continue will restart I/O. */ void scsi_req_data(SCSIRequest *req, int len) { uint8_t *buf; if (req->io_canceled) { trace_scsi_req_data_canceled(req->dev->id, req->lun, req->tag, len); return; } trace_scsi_req_data(req->dev->id, req->lun, req->tag, len); assert(req->cmd.mode != SCSI_XFER_NONE); if (!req->sg) { req->resid -= len; req->bus->info->transfer_data(req, len); return; } /* If the device calls scsi_req_data and the HBA specified a * scatter/gather list, the transfer has to happen in a single * step. */ assert(!req->dma_started); req->dma_started = true; buf = scsi_req_get_buf(req); if (req->cmd.mode == SCSI_XFER_FROM_DEV) { req->resid = dma_buf_read(buf, len, req->sg); } else { req->resid = dma_buf_write(buf, len, req->sg); } scsi_req_continue(req); } void scsi_req_print(SCSIRequest *req) { FILE *fp = stderr; int i; fprintf(fp, "[%s id=%d] %s", req->dev->qdev.parent_bus->name, req->dev->id, scsi_command_name(req->cmd.buf[0])); for (i = 1; i < req->cmd.len; i++) { fprintf(fp, " 0x%02x", req->cmd.buf[i]); } switch (req->cmd.mode) { case SCSI_XFER_NONE: fprintf(fp, " - none\n"); break; case SCSI_XFER_FROM_DEV: fprintf(fp, " - from-dev len=%zd\n", req->cmd.xfer); break; case SCSI_XFER_TO_DEV: fprintf(fp, " - to-dev len=%zd\n", req->cmd.xfer); break; default: fprintf(fp, " - Oops\n"); break; } } void scsi_req_complete(SCSIRequest *req, int status) { assert(req->status == -1); req->status = status; assert(req->sense_len <= sizeof(req->sense)); if (status == GOOD) { req->sense_len = 0; } if (req->sense_len) { memcpy(req->dev->sense, req->sense, req->sense_len); req->dev->sense_len = req->sense_len; req->dev->sense_is_ua = (req->ops == &reqops_unit_attention); } else { req->dev->sense_len = 0; req->dev->sense_is_ua = false; } /* * Unit attention state is now stored in the device's sense buffer * if the HBA didn't do autosense. Clear the pending unit attention * flags. */ scsi_clear_unit_attention(req); scsi_req_ref(req); scsi_req_dequeue(req); req->bus->info->complete(req, req->status, req->resid); /* Cancelled requests might end up being completed instead of cancelled */ notifier_list_notify(&req->cancel_notifiers, req); scsi_req_unref(req); } /* Called by the devices when the request is canceled. */ void scsi_req_cancel_complete(SCSIRequest *req) { assert(req->io_canceled); if (req->bus->info->cancel) { req->bus->info->cancel(req); } notifier_list_notify(&req->cancel_notifiers, req); scsi_req_unref(req); } /* Cancel @req asynchronously. @notifier is added to @req's cancellation * notifier list, the bus will be notified the requests cancellation is * completed. * */ void scsi_req_cancel_async(SCSIRequest *req, Notifier *notifier) { trace_scsi_req_cancel(req->dev->id, req->lun, req->tag); if (notifier) { notifier_list_add(&req->cancel_notifiers, notifier); } if (req->io_canceled) { /* A blk_aio_cancel_async is pending; when it finishes, * scsi_req_cancel_complete will be called and will * call the notifier we just added. Just wait for that. */ assert(req->aiocb); return; } /* Dropped in scsi_req_cancel_complete. */ scsi_req_ref(req); scsi_req_dequeue(req); req->io_canceled = true; if (req->aiocb) { blk_aio_cancel_async(req->aiocb); } else { scsi_req_cancel_complete(req); } } void scsi_req_cancel(SCSIRequest *req) { trace_scsi_req_cancel(req->dev->id, req->lun, req->tag); if (!req->enqueued) { return; } assert(!req->io_canceled); /* Dropped in scsi_req_cancel_complete. */ scsi_req_ref(req); scsi_req_dequeue(req); req->io_canceled = true; if (req->aiocb) { blk_aio_cancel(req->aiocb); } else { scsi_req_cancel_complete(req); } } static int scsi_ua_precedence(SCSISense sense) { if (sense.key != UNIT_ATTENTION) { return INT_MAX; } if (sense.asc == 0x29 && sense.ascq == 0x04) { /* DEVICE INTERNAL RESET goes with POWER ON OCCURRED */ return 1; } else if (sense.asc == 0x3F && sense.ascq == 0x01) { /* MICROCODE HAS BEEN CHANGED goes with SCSI BUS RESET OCCURRED */ return 2; } else if (sense.asc == 0x29 && (sense.ascq == 0x05 || sense.ascq == 0x06)) { /* These two go with "all others". */ ; } else if (sense.asc == 0x29 && sense.ascq <= 0x07) { /* POWER ON, RESET OR BUS DEVICE RESET OCCURRED = 0 * POWER ON OCCURRED = 1 * SCSI BUS RESET OCCURRED = 2 * BUS DEVICE RESET FUNCTION OCCURRED = 3 * I_T NEXUS LOSS OCCURRED = 7 */ return sense.ascq; } else if (sense.asc == 0x2F && sense.ascq == 0x01) { /* COMMANDS CLEARED BY POWER LOSS NOTIFICATION */ return 8; } return (sense.asc << 8) | sense.ascq; } void scsi_device_set_ua(SCSIDevice *sdev, SCSISense sense) { int prec1, prec2; if (sense.key != UNIT_ATTENTION) { return; } trace_scsi_device_set_ua(sdev->id, sdev->lun, sense.key, sense.asc, sense.ascq); /* * Override a pre-existing unit attention condition, except for a more * important reset condition. */ prec1 = scsi_ua_precedence(sdev->unit_attention); prec2 = scsi_ua_precedence(sense); if (prec2 < prec1) { sdev->unit_attention = sense; } } void scsi_device_purge_requests(SCSIDevice *sdev, SCSISense sense) { SCSIRequest *req; aio_context_acquire(blk_get_aio_context(sdev->conf.blk)); while (!QTAILQ_EMPTY(&sdev->requests)) { req = QTAILQ_FIRST(&sdev->requests); scsi_req_cancel_async(req, NULL); } blk_drain(sdev->conf.blk); aio_context_release(blk_get_aio_context(sdev->conf.blk)); scsi_device_set_ua(sdev, sense); } static char *scsibus_get_dev_path(DeviceState *dev) { SCSIDevice *d = SCSI_DEVICE(dev); DeviceState *hba = dev->parent_bus->parent; char *id; char *path; id = qdev_get_dev_path(hba); if (id) { path = g_strdup_printf("%s/%d:%d:%d", id, d->channel, d->id, d->lun); } else { path = g_strdup_printf("%d:%d:%d", d->channel, d->id, d->lun); } g_free(id); return path; } static char *scsibus_get_fw_dev_path(DeviceState *dev) { SCSIDevice *d = SCSI_DEVICE(dev); return g_strdup_printf("channel@%x/%s@%x,%x", d->channel, qdev_fw_name(dev), d->id, d->lun); } SCSIDevice *scsi_device_find(SCSIBus *bus, int channel, int id, int lun) { BusChild *kid; SCSIDevice *target_dev = NULL; QTAILQ_FOREACH_REVERSE(kid, &bus->qbus.children, ChildrenHead, sibling) { DeviceState *qdev = kid->child; SCSIDevice *dev = SCSI_DEVICE(qdev); if (dev->channel == channel && dev->id == id) { if (dev->lun == lun) { return dev; } target_dev = dev; } } return target_dev; } /* SCSI request list. For simplicity, pv points to the whole device */ static void put_scsi_requests(QEMUFile *f, void *pv, size_t size) { SCSIDevice *s = pv; SCSIBus *bus = DO_UPCAST(SCSIBus, qbus, s->qdev.parent_bus); SCSIRequest *req; QTAILQ_FOREACH(req, &s->requests, next) { assert(!req->io_canceled); assert(req->status == -1); assert(req->enqueued); qemu_put_sbyte(f, req->retry ? 1 : 2); qemu_put_buffer(f, req->cmd.buf, sizeof(req->cmd.buf)); qemu_put_be32s(f, &req->tag); qemu_put_be32s(f, &req->lun); if (bus->info->save_request) { bus->info->save_request(f, req); } if (req->ops->save_request) { req->ops->save_request(f, req); } } qemu_put_sbyte(f, 0); } static int get_scsi_requests(QEMUFile *f, void *pv, size_t size) { SCSIDevice *s = pv; SCSIBus *bus = DO_UPCAST(SCSIBus, qbus, s->qdev.parent_bus); int8_t sbyte; while ((sbyte = qemu_get_sbyte(f)) > 0) { uint8_t buf[SCSI_CMD_BUF_SIZE]; uint32_t tag; uint32_t lun; SCSIRequest *req; qemu_get_buffer(f, buf, sizeof(buf)); qemu_get_be32s(f, &tag); qemu_get_be32s(f, &lun); req = scsi_req_new(s, tag, lun, buf, NULL); req->retry = (sbyte == 1); if (bus->info->load_request) { req->hba_private = bus->info->load_request(f, req); } if (req->ops->load_request) { req->ops->load_request(f, req); } /* Just restart it later. */ scsi_req_enqueue_internal(req); /* At this point, the request will be kept alive by the reference * added by scsi_req_enqueue_internal, so we can release our reference. * The HBA of course will add its own reference in the load_request * callback if it needs to hold on the SCSIRequest. */ scsi_req_unref(req); } return 0; } static const VMStateInfo vmstate_info_scsi_requests = { .name = "scsi-requests", .get = get_scsi_requests, .put = put_scsi_requests, }; static bool scsi_sense_state_needed(void *opaque) { SCSIDevice *s = opaque; return s->sense_len > SCSI_SENSE_BUF_SIZE_OLD; } static const VMStateDescription vmstate_scsi_sense_state = { .name = "SCSIDevice/sense", .version_id = 1, .minimum_version_id = 1, .needed = scsi_sense_state_needed, .fields = (VMStateField[]) { VMSTATE_UINT8_SUB_ARRAY(sense, SCSIDevice, SCSI_SENSE_BUF_SIZE_OLD, SCSI_SENSE_BUF_SIZE - SCSI_SENSE_BUF_SIZE_OLD), VMSTATE_END_OF_LIST() } }; const VMStateDescription vmstate_scsi_device = { .name = "SCSIDevice", .version_id = 1, .minimum_version_id = 1, .fields = (VMStateField[]) { VMSTATE_UINT8(unit_attention.key, SCSIDevice), VMSTATE_UINT8(unit_attention.asc, SCSIDevice), VMSTATE_UINT8(unit_attention.ascq, SCSIDevice), VMSTATE_BOOL(sense_is_ua, SCSIDevice), VMSTATE_UINT8_SUB_ARRAY(sense, SCSIDevice, 0, SCSI_SENSE_BUF_SIZE_OLD), VMSTATE_UINT32(sense_len, SCSIDevice), { .name = "requests", .version_id = 0, .field_exists = NULL, .size = 0, /* ouch */ .info = &vmstate_info_scsi_requests, .flags = VMS_SINGLE, .offset = 0, }, VMSTATE_END_OF_LIST() }, .subsections = (const VMStateDescription*[]) { &vmstate_scsi_sense_state, NULL } }; static void scsi_device_class_init(ObjectClass *klass, void *data) { DeviceClass *k = DEVICE_CLASS(klass); set_bit(DEVICE_CATEGORY_STORAGE, k->categories); k->bus_type = TYPE_SCSI_BUS; k->realize = scsi_qdev_realize; k->unrealize = scsi_qdev_unrealize; k->props = scsi_props; } static void scsi_dev_instance_init(Object *obj) { DeviceState *dev = DEVICE(obj); SCSIDevice *s = SCSI_DEVICE(dev); device_add_bootindex_property(obj, &s->conf.bootindex, "bootindex", NULL, &s->qdev, NULL); } static const TypeInfo scsi_device_type_info = { .name = TYPE_SCSI_DEVICE, .parent = TYPE_DEVICE, .instance_size = sizeof(SCSIDevice), .abstract = true, .class_size = sizeof(SCSIDeviceClass), .class_init = scsi_device_class_init, .instance_init = scsi_dev_instance_init, }; static void scsi_register_types(void) { type_register_static(&scsi_bus_info); type_register_static(&scsi_device_type_info); } type_init(scsi_register_types)