/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2007 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * LDoms virtual disk client (vdc) device driver * * This driver runs on a guest logical domain and communicates with the virtual * disk server (vds) driver running on the service domain which is exporting * virtualized "disks" to the guest logical domain. * * The driver can be divided into four sections: * * 1) generic device driver housekeeping * _init, _fini, attach, detach, ops structures, etc. * * 2) communication channel setup * Setup the communications link over the LDC channel that vdc uses to * talk to the vDisk server. Initialise the descriptor ring which * allows the LDC clients to transfer data via memory mappings. * * 3) Support exported to upper layers (filesystems, etc) * The upper layers call into vdc via strategy(9E) and DKIO(7I) * ioctl calls. vdc will copy the data to be written to the descriptor * ring or maps the buffer to store the data read by the vDisk * server into the descriptor ring. It then sends a message to the * vDisk server requesting it to complete the operation. * * 4) Handling responses from vDisk server. * The vDisk server will ACK some or all of the messages vdc sends to it * (this is configured during the handshake). Upon receipt of an ACK * vdc will check the descriptor ring and signal to the upper layer * code waiting on the IO. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* * function prototypes */ /* standard driver functions */ static int vdc_open(dev_t *dev, int flag, int otyp, cred_t *cred); static int vdc_close(dev_t dev, int flag, int otyp, cred_t *cred); static int vdc_strategy(struct buf *buf); static int vdc_print(dev_t dev, char *str); static int vdc_dump(dev_t dev, caddr_t addr, daddr_t blkno, int nblk); static int vdc_read(dev_t dev, struct uio *uio, cred_t *cred); static int vdc_write(dev_t dev, struct uio *uio, cred_t *cred); static int vdc_ioctl(dev_t dev, int cmd, intptr_t arg, int mode, cred_t *credp, int *rvalp); static int vdc_aread(dev_t dev, struct aio_req *aio, cred_t *cred); static int vdc_awrite(dev_t dev, struct aio_req *aio, cred_t *cred); static int vdc_getinfo(dev_info_t *dip, ddi_info_cmd_t cmd, void *arg, void **resultp); static int vdc_attach(dev_info_t *dip, ddi_attach_cmd_t cmd); static int vdc_detach(dev_info_t *dip, ddi_detach_cmd_t cmd); /* setup */ static void vdc_min(struct buf *bufp); static int vdc_send(vdc_t *vdc, caddr_t pkt, size_t *msglen); static int vdc_do_ldc_init(vdc_t *vdc, md_t *mdp, mde_cookie_t vd_node); static int vdc_start_ldc_connection(vdc_t *vdc); static int vdc_create_device_nodes(vdc_t *vdc); static int vdc_create_device_nodes_efi(vdc_t *vdc); static int vdc_create_device_nodes_vtoc(vdc_t *vdc); static int vdc_create_device_nodes_props(vdc_t *vdc); static int vdc_get_md_node(dev_info_t *dip, md_t **mdpp, mde_cookie_t *vd_nodep, mde_cookie_t *vd_portp); static int vdc_get_ldc_id(md_t *, mde_cookie_t, uint64_t *); static int vdc_do_ldc_up(vdc_t *vdc); static void vdc_terminate_ldc(vdc_t *vdc); static int vdc_init_descriptor_ring(vdc_t *vdc); static void vdc_destroy_descriptor_ring(vdc_t *vdc); static int vdc_setup_devid(vdc_t *vdc); static void vdc_store_label_efi(vdc_t *vdc, struct dk_gpt *efi); static void vdc_store_label_vtoc(vdc_t *, struct dk_geom *, struct vtoc *); static void vdc_store_label_unk(vdc_t *vdc); static boolean_t vdc_is_opened(vdc_t *vdc); /* handshake with vds */ static int vdc_init_ver_negotiation(vdc_t *vdc, vio_ver_t ver); static int vdc_ver_negotiation(vdc_t *vdcp); static int vdc_init_attr_negotiation(vdc_t *vdc); static int vdc_attr_negotiation(vdc_t *vdcp); static int vdc_init_dring_negotiate(vdc_t *vdc); static int vdc_dring_negotiation(vdc_t *vdcp); static int vdc_send_rdx(vdc_t *vdcp); static int vdc_rdx_exchange(vdc_t *vdcp); static boolean_t vdc_is_supported_version(vio_ver_msg_t *ver_msg); /* processing incoming messages from vDisk server */ static void vdc_process_msg_thread(vdc_t *vdc); static int vdc_recv(vdc_t *vdc, vio_msg_t *msgp, size_t *nbytesp); static uint_t vdc_handle_cb(uint64_t event, caddr_t arg); static int vdc_process_data_msg(vdc_t *vdc, vio_msg_t *msg); static int vdc_handle_ver_msg(vdc_t *vdc, vio_ver_msg_t *ver_msg); static int vdc_handle_attr_msg(vdc_t *vdc, vd_attr_msg_t *attr_msg); static int vdc_handle_dring_reg_msg(vdc_t *vdc, vio_dring_reg_msg_t *msg); static int vdc_send_request(vdc_t *vdcp, int operation, caddr_t addr, size_t nbytes, int slice, diskaddr_t offset, int cb_type, void *cb_arg, vio_desc_direction_t dir); static int vdc_map_to_shared_dring(vdc_t *vdcp, int idx); static int vdc_populate_descriptor(vdc_t *vdcp, int operation, caddr_t addr, size_t nbytes, int slice, diskaddr_t offset, int cb_type, void *cb_arg, vio_desc_direction_t dir); static int vdc_do_sync_op(vdc_t *vdcp, int operation, caddr_t addr, size_t nbytes, int slice, diskaddr_t offset, int cb_type, void *cb_arg, vio_desc_direction_t dir, boolean_t); static int vdc_wait_for_response(vdc_t *vdcp, vio_msg_t *msgp); static int vdc_drain_response(vdc_t *vdcp); static int vdc_depopulate_descriptor(vdc_t *vdc, uint_t idx); static int vdc_populate_mem_hdl(vdc_t *vdcp, vdc_local_desc_t *ldep); static int vdc_verify_seq_num(vdc_t *vdc, vio_dring_msg_t *dring_msg); /* dkio */ static int vd_process_ioctl(dev_t dev, int cmd, caddr_t arg, int mode, int *rvalp); static int vd_process_efi_ioctl(dev_t dev, int cmd, caddr_t arg, int mode); static void vdc_create_fake_geometry(vdc_t *vdc); static int vdc_validate_geometry(vdc_t *vdc); static void vdc_validate(vdc_t *vdc); static void vdc_validate_task(void *arg); static int vdc_null_copy_func(vdc_t *vdc, void *from, void *to, int mode, int dir); static int vdc_get_wce_convert(vdc_t *vdc, void *from, void *to, int mode, int dir); static int vdc_set_wce_convert(vdc_t *vdc, void *from, void *to, int mode, int dir); static int vdc_get_vtoc_convert(vdc_t *vdc, void *from, void *to, int mode, int dir); static int vdc_set_vtoc_convert(vdc_t *vdc, void *from, void *to, int mode, int dir); static int vdc_get_geom_convert(vdc_t *vdc, void *from, void *to, int mode, int dir); static int vdc_set_geom_convert(vdc_t *vdc, void *from, void *to, int mode, int dir); static int vdc_get_efi_convert(vdc_t *vdc, void *from, void *to, int mode, int dir); static int vdc_set_efi_convert(vdc_t *vdc, void *from, void *to, int mode, int dir); static void vdc_ownership_update(vdc_t *vdc, int ownership_flags); static int vdc_access_set(vdc_t *vdc, uint64_t flags, int mode); static vdc_io_t *vdc_failfast_io_queue(vdc_t *vdc, struct buf *buf); static int vdc_failfast_check_resv(vdc_t *vdc); /* * Module variables */ /* * Tunable variables to control how long vdc waits before timing out on * various operations */ static int vdc_hshake_retries = 3; static int vdc_timeout = 0; /* units: seconds */ static uint64_t vdc_hz_min_ldc_delay; static uint64_t vdc_min_timeout_ldc = 1 * MILLISEC; static uint64_t vdc_hz_max_ldc_delay; static uint64_t vdc_max_timeout_ldc = 100 * MILLISEC; static uint64_t vdc_ldc_read_init_delay = 1 * MILLISEC; static uint64_t vdc_ldc_read_max_delay = 100 * MILLISEC; /* values for dumping - need to run in a tighter loop */ static uint64_t vdc_usec_timeout_dump = 100 * MILLISEC; /* 0.1s units: ns */ static int vdc_dump_retries = 100; static uint16_t vdc_scsi_timeout = 60; /* 60s units: seconds */ static uint64_t vdc_ownership_delay = 6 * MICROSEC; /* 6s units: usec */ /* Count of the number of vdc instances attached */ static volatile uint32_t vdc_instance_count = 0; /* Tunable to log all SCSI errors */ static boolean_t vdc_scsi_log_error = B_FALSE; /* Soft state pointer */ static void *vdc_state; /* * Controlling the verbosity of the error/debug messages * * vdc_msglevel - controls level of messages * vdc_matchinst - 64-bit variable where each bit corresponds * to the vdc instance the vdc_msglevel applies. */ int vdc_msglevel = 0x0; uint64_t vdc_matchinst = 0ull; /* * Supported vDisk protocol version pairs. * * The first array entry is the latest and preferred version. */ static const vio_ver_t vdc_version[] = {{1, 1}}; static struct cb_ops vdc_cb_ops = { vdc_open, /* cb_open */ vdc_close, /* cb_close */ vdc_strategy, /* cb_strategy */ vdc_print, /* cb_print */ vdc_dump, /* cb_dump */ vdc_read, /* cb_read */ vdc_write, /* cb_write */ vdc_ioctl, /* cb_ioctl */ nodev, /* cb_devmap */ nodev, /* cb_mmap */ nodev, /* cb_segmap */ nochpoll, /* cb_chpoll */ ddi_prop_op, /* cb_prop_op */ NULL, /* cb_str */ D_MP | D_64BIT, /* cb_flag */ CB_REV, /* cb_rev */ vdc_aread, /* cb_aread */ vdc_awrite /* cb_awrite */ }; static struct dev_ops vdc_ops = { DEVO_REV, /* devo_rev */ 0, /* devo_refcnt */ vdc_getinfo, /* devo_getinfo */ nulldev, /* devo_identify */ nulldev, /* devo_probe */ vdc_attach, /* devo_attach */ vdc_detach, /* devo_detach */ nodev, /* devo_reset */ &vdc_cb_ops, /* devo_cb_ops */ NULL, /* devo_bus_ops */ nulldev /* devo_power */ }; static struct modldrv modldrv = { &mod_driverops, "virtual disk client", &vdc_ops, }; static struct modlinkage modlinkage = { MODREV_1, &modldrv, NULL }; /* -------------------------------------------------------------------------- */ /* * Device Driver housekeeping and setup */ int _init(void) { int status; if ((status = ddi_soft_state_init(&vdc_state, sizeof (vdc_t), 1)) != 0) return (status); if ((status = mod_install(&modlinkage)) != 0) ddi_soft_state_fini(&vdc_state); vdc_efi_init(vd_process_efi_ioctl); return (status); } int _info(struct modinfo *modinfop) { return (mod_info(&modlinkage, modinfop)); } int _fini(void) { int status; if ((status = mod_remove(&modlinkage)) != 0) return (status); vdc_efi_fini(); ddi_soft_state_fini(&vdc_state); return (0); } static int vdc_getinfo(dev_info_t *dip, ddi_info_cmd_t cmd, void *arg, void **resultp) { _NOTE(ARGUNUSED(dip)) int instance = VDCUNIT((dev_t)arg); vdc_t *vdc = NULL; switch (cmd) { case DDI_INFO_DEVT2DEVINFO: if ((vdc = ddi_get_soft_state(vdc_state, instance)) == NULL) { *resultp = NULL; return (DDI_FAILURE); } *resultp = vdc->dip; return (DDI_SUCCESS); case DDI_INFO_DEVT2INSTANCE: *resultp = (void *)(uintptr_t)instance; return (DDI_SUCCESS); default: *resultp = NULL; return (DDI_FAILURE); } } static int vdc_detach(dev_info_t *dip, ddi_detach_cmd_t cmd) { kt_did_t failfast_tid, ownership_tid; int instance; int rv; vdc_t *vdc = NULL; switch (cmd) { case DDI_DETACH: /* the real work happens below */ break; case DDI_SUSPEND: /* nothing to do for this non-device */ return (DDI_SUCCESS); default: return (DDI_FAILURE); } ASSERT(cmd == DDI_DETACH); instance = ddi_get_instance(dip); DMSGX(1, "[%d] Entered\n", instance); if ((vdc = ddi_get_soft_state(vdc_state, instance)) == NULL) { cmn_err(CE_NOTE, "[%d] Couldn't get state structure", instance); return (DDI_FAILURE); } /* * This function is called when vdc is detached or if it has failed to * attach. In that case, the attach may have fail before the vdisk type * has been set so we can't call vdc_is_opened(). However as the attach * has failed, we know that the vdisk is not opened and we can safely * detach. */ if (vdc->vdisk_type != VD_DISK_TYPE_UNK && vdc_is_opened(vdc)) { DMSG(vdc, 0, "[%d] Cannot detach: device is open", instance); return (DDI_FAILURE); } if (vdc->dkio_flush_pending) { DMSG(vdc, 0, "[%d] Cannot detach: %d outstanding DKIO flushes\n", instance, vdc->dkio_flush_pending); return (DDI_FAILURE); } if (vdc->validate_pending) { DMSG(vdc, 0, "[%d] Cannot detach: %d outstanding validate request\n", instance, vdc->validate_pending); return (DDI_FAILURE); } DMSG(vdc, 0, "[%d] proceeding...\n", instance); /* If we took ownership, release ownership */ mutex_enter(&vdc->ownership_lock); if (vdc->ownership & VDC_OWNERSHIP_GRANTED) { rv = vdc_access_set(vdc, VD_ACCESS_SET_CLEAR, FKIOCTL); if (rv == 0) { vdc_ownership_update(vdc, VDC_OWNERSHIP_NONE); } } mutex_exit(&vdc->ownership_lock); /* mark instance as detaching */ vdc->lifecycle = VDC_LC_DETACHING; /* * try and disable callbacks to prevent another handshake */ rv = ldc_set_cb_mode(vdc->ldc_handle, LDC_CB_DISABLE); DMSG(vdc, 0, "callback disabled (rv=%d)\n", rv); if (vdc->initialized & VDC_THREAD) { mutex_enter(&vdc->read_lock); if ((vdc->read_state == VDC_READ_WAITING) || (vdc->read_state == VDC_READ_RESET)) { vdc->read_state = VDC_READ_RESET; cv_signal(&vdc->read_cv); } mutex_exit(&vdc->read_lock); /* wake up any thread waiting for connection to come online */ mutex_enter(&vdc->lock); if (vdc->state == VDC_STATE_INIT_WAITING) { DMSG(vdc, 0, "[%d] write reset - move to resetting state...\n", instance); vdc->state = VDC_STATE_RESETTING; cv_signal(&vdc->initwait_cv); } mutex_exit(&vdc->lock); /* now wait until state transitions to VDC_STATE_DETACH */ thread_join(vdc->msg_proc_thr->t_did); ASSERT(vdc->state == VDC_STATE_DETACH); DMSG(vdc, 0, "[%d] Reset thread exit and join ..\n", vdc->instance); } mutex_enter(&vdc->lock); if (vdc->initialized & VDC_DRING) vdc_destroy_descriptor_ring(vdc); if (vdc->initialized & VDC_LDC) vdc_terminate_ldc(vdc); if (vdc->failfast_thread) { failfast_tid = vdc->failfast_thread->t_did; vdc->failfast_interval = 0; cv_signal(&vdc->failfast_cv); } else { failfast_tid = 0; } if (vdc->ownership & VDC_OWNERSHIP_WANTED) { ownership_tid = vdc->ownership_thread->t_did; vdc->ownership = VDC_OWNERSHIP_NONE; cv_signal(&vdc->ownership_cv); } else { ownership_tid = 0; } mutex_exit(&vdc->lock); if (failfast_tid != 0) thread_join(failfast_tid); if (ownership_tid != 0) thread_join(ownership_tid); if (vdc->initialized & VDC_MINOR) { ddi_prop_remove_all(dip); ddi_remove_minor_node(dip, NULL); } if (vdc->initialized & VDC_LOCKS) { mutex_destroy(&vdc->lock); mutex_destroy(&vdc->read_lock); mutex_destroy(&vdc->ownership_lock); cv_destroy(&vdc->initwait_cv); cv_destroy(&vdc->dring_free_cv); cv_destroy(&vdc->membind_cv); cv_destroy(&vdc->sync_pending_cv); cv_destroy(&vdc->sync_blocked_cv); cv_destroy(&vdc->read_cv); cv_destroy(&vdc->running_cv); cv_destroy(&vdc->ownership_cv); cv_destroy(&vdc->failfast_cv); cv_destroy(&vdc->failfast_io_cv); } if (vdc->minfo) kmem_free(vdc->minfo, sizeof (struct dk_minfo)); if (vdc->cinfo) kmem_free(vdc->cinfo, sizeof (struct dk_cinfo)); if (vdc->vtoc) kmem_free(vdc->vtoc, sizeof (struct vtoc)); if (vdc->geom) kmem_free(vdc->geom, sizeof (struct dk_geom)); if (vdc->devid) { ddi_devid_unregister(dip); ddi_devid_free(vdc->devid); } if (vdc->initialized & VDC_SOFT_STATE) ddi_soft_state_free(vdc_state, instance); DMSG(vdc, 0, "[%d] End %p\n", instance, (void *)vdc); return (DDI_SUCCESS); } static int vdc_do_attach(dev_info_t *dip) { int instance; vdc_t *vdc = NULL; int status; md_t *mdp; mde_cookie_t vd_node, vd_port; ASSERT(dip != NULL); instance = ddi_get_instance(dip); if (ddi_soft_state_zalloc(vdc_state, instance) != DDI_SUCCESS) { cmn_err(CE_NOTE, "[%d] Couldn't alloc state structure", instance); return (DDI_FAILURE); } if ((vdc = ddi_get_soft_state(vdc_state, instance)) == NULL) { cmn_err(CE_NOTE, "[%d] Couldn't get state structure", instance); return (DDI_FAILURE); } /* * We assign the value to initialized in this case to zero out the * variable and then set bits in it to indicate what has been done */ vdc->initialized = VDC_SOFT_STATE; vdc_hz_min_ldc_delay = drv_usectohz(vdc_min_timeout_ldc); vdc_hz_max_ldc_delay = drv_usectohz(vdc_max_timeout_ldc); vdc->dip = dip; vdc->instance = instance; vdc->vdisk_type = VD_DISK_TYPE_UNK; vdc->vdisk_label = VD_DISK_LABEL_UNK; vdc->state = VDC_STATE_INIT; vdc->lifecycle = VDC_LC_ATTACHING; vdc->ldc_state = 0; vdc->session_id = 0; vdc->block_size = DEV_BSIZE; vdc->max_xfer_sz = maxphys / DEV_BSIZE; /* * We assume, for now, that the vDisk server will export 'read' * operations to us at a minimum (this is needed because of checks * in vdc for supported operations early in the handshake process). * The vDisk server will return ENOTSUP if this is not the case. * The value will be overwritten during the attribute exchange with * the bitmask of operations exported by server. */ vdc->operations = VD_OP_MASK_READ; vdc->vtoc = NULL; vdc->geom = NULL; vdc->cinfo = NULL; vdc->minfo = NULL; mutex_init(&vdc->lock, NULL, MUTEX_DRIVER, NULL); cv_init(&vdc->initwait_cv, NULL, CV_DRIVER, NULL); cv_init(&vdc->dring_free_cv, NULL, CV_DRIVER, NULL); cv_init(&vdc->membind_cv, NULL, CV_DRIVER, NULL); cv_init(&vdc->running_cv, NULL, CV_DRIVER, NULL); vdc->threads_pending = 0; vdc->sync_op_pending = B_FALSE; vdc->sync_op_blocked = B_FALSE; cv_init(&vdc->sync_pending_cv, NULL, CV_DRIVER, NULL); cv_init(&vdc->sync_blocked_cv, NULL, CV_DRIVER, NULL); mutex_init(&vdc->ownership_lock, NULL, MUTEX_DRIVER, NULL); cv_init(&vdc->ownership_cv, NULL, CV_DRIVER, NULL); cv_init(&vdc->failfast_cv, NULL, CV_DRIVER, NULL); cv_init(&vdc->failfast_io_cv, NULL, CV_DRIVER, NULL); /* init blocking msg read functionality */ mutex_init(&vdc->read_lock, NULL, MUTEX_DRIVER, NULL); cv_init(&vdc->read_cv, NULL, CV_DRIVER, NULL); vdc->read_state = VDC_READ_IDLE; vdc->initialized |= VDC_LOCKS; /* get device and port MD node for this disk instance */ if (vdc_get_md_node(dip, &mdp, &vd_node, &vd_port) != 0) { cmn_err(CE_NOTE, "[%d] Could not get machine description node", instance); return (DDI_FAILURE); } /* set the connection timeout */ if (vd_port == NULL || (md_get_prop_val(mdp, vd_port, VDC_MD_TIMEOUT, &vdc->ctimeout) != 0)) { vdc->ctimeout = 0; } /* initialise LDC channel which will be used to communicate with vds */ status = vdc_do_ldc_init(vdc, mdp, vd_node); (void) md_fini_handle(mdp); if (status != 0) { cmn_err(CE_NOTE, "[%d] Couldn't initialize LDC", instance); goto return_status; } /* initialize the thread responsible for managing state with server */ vdc->msg_proc_thr = thread_create(NULL, 0, vdc_process_msg_thread, vdc, 0, &p0, TS_RUN, minclsyspri); if (vdc->msg_proc_thr == NULL) { cmn_err(CE_NOTE, "[%d] Failed to create msg processing thread", instance); return (DDI_FAILURE); } vdc->initialized |= VDC_THREAD; atomic_inc_32(&vdc_instance_count); /* * Check the disk label. This will send requests and do the handshake. * We don't really care about the disk label now. What we really need is * the handshake do be done so that we know the type of the disk (slice * or full disk) and the appropriate device nodes can be created. */ vdc->vdisk_label = VD_DISK_LABEL_UNK; vdc->vtoc = kmem_zalloc(sizeof (struct vtoc), KM_SLEEP); vdc->geom = kmem_zalloc(sizeof (struct dk_geom), KM_SLEEP); vdc->minfo = kmem_zalloc(sizeof (struct dk_minfo), KM_SLEEP); mutex_enter(&vdc->lock); (void) vdc_validate_geometry(vdc); mutex_exit(&vdc->lock); /* * Now that we have the device info we can create the * device nodes and properties */ status = vdc_create_device_nodes(vdc); if (status) { DMSG(vdc, 0, "[%d] Failed to create device nodes", instance); goto return_status; } status = vdc_create_device_nodes_props(vdc); if (status) { DMSG(vdc, 0, "[%d] Failed to create device nodes" " properties (%d)", instance, status); goto return_status; } /* * Setup devid */ if (vdc_setup_devid(vdc)) { DMSG(vdc, 0, "[%d] No device id available\n", instance); } ddi_report_dev(dip); vdc->lifecycle = VDC_LC_ONLINE; DMSG(vdc, 0, "[%d] Attach tasks successful\n", instance); return_status: DMSG(vdc, 0, "[%d] Attach completed\n", instance); return (status); } static int vdc_attach(dev_info_t *dip, ddi_attach_cmd_t cmd) { int status; switch (cmd) { case DDI_ATTACH: if ((status = vdc_do_attach(dip)) != 0) (void) vdc_detach(dip, DDI_DETACH); return (status); case DDI_RESUME: /* nothing to do for this non-device */ return (DDI_SUCCESS); default: return (DDI_FAILURE); } } static int vdc_do_ldc_init(vdc_t *vdc, md_t *mdp, mde_cookie_t vd_node) { int status = 0; ldc_status_t ldc_state; ldc_attr_t ldc_attr; uint64_t ldc_id = 0; ASSERT(vdc != NULL); vdc->initialized |= VDC_LDC; if ((status = vdc_get_ldc_id(mdp, vd_node, &ldc_id)) != 0) { DMSG(vdc, 0, "[%d] Failed to get LDC channel ID property", vdc->instance); return (EIO); } DMSGX(0, "[%d] LDC id is 0x%lx\n", vdc->instance, ldc_id); vdc->ldc_id = ldc_id; ldc_attr.devclass = LDC_DEV_BLK; ldc_attr.instance = vdc->instance; ldc_attr.mode = LDC_MODE_UNRELIABLE; /* unreliable transport */ ldc_attr.mtu = VD_LDC_MTU; if ((vdc->initialized & VDC_LDC_INIT) == 0) { status = ldc_init(ldc_id, &ldc_attr, &vdc->ldc_handle); if (status != 0) { DMSG(vdc, 0, "[%d] ldc_init(chan %ld) returned %d", vdc->instance, ldc_id, status); return (status); } vdc->initialized |= VDC_LDC_INIT; } status = ldc_status(vdc->ldc_handle, &ldc_state); if (status != 0) { DMSG(vdc, 0, "[%d] Cannot discover LDC status [err=%d]", vdc->instance, status); return (status); } vdc->ldc_state = ldc_state; if ((vdc->initialized & VDC_LDC_CB) == 0) { status = ldc_reg_callback(vdc->ldc_handle, vdc_handle_cb, (caddr_t)vdc); if (status != 0) { DMSG(vdc, 0, "[%d] LDC callback reg. failed (%d)", vdc->instance, status); return (status); } vdc->initialized |= VDC_LDC_CB; } vdc->initialized |= VDC_LDC; /* * At this stage we have initialised LDC, we will now try and open * the connection. */ if (vdc->ldc_state == LDC_INIT) { status = ldc_open(vdc->ldc_handle); if (status != 0) { DMSG(vdc, 0, "[%d] ldc_open(chan %ld) returned %d", vdc->instance, vdc->ldc_id, status); return (status); } vdc->initialized |= VDC_LDC_OPEN; } return (status); } static int vdc_start_ldc_connection(vdc_t *vdc) { int status = 0; ASSERT(vdc != NULL); ASSERT(MUTEX_HELD(&vdc->lock)); status = vdc_do_ldc_up(vdc); DMSG(vdc, 0, "[%d] Finished bringing up LDC\n", vdc->instance); return (status); } static int vdc_stop_ldc_connection(vdc_t *vdcp) { int status; DMSG(vdcp, 0, ": Resetting connection to vDisk server : state %d\n", vdcp->state); status = ldc_down(vdcp->ldc_handle); DMSG(vdcp, 0, "ldc_down() = %d\n", status); vdcp->initialized &= ~VDC_HANDSHAKE; DMSG(vdcp, 0, "initialized=%x\n", vdcp->initialized); return (status); } static int vdc_create_device_nodes_efi(vdc_t *vdc) { ddi_remove_minor_node(vdc->dip, "h"); ddi_remove_minor_node(vdc->dip, "h,raw"); if (ddi_create_minor_node(vdc->dip, "wd", S_IFBLK, VD_MAKE_DEV(vdc->instance, VD_EFI_WD_SLICE), DDI_NT_BLOCK, 0) != DDI_SUCCESS) { cmn_err(CE_NOTE, "[%d] Couldn't add block node 'wd'", vdc->instance); return (EIO); } /* if any device node is created we set this flag */ vdc->initialized |= VDC_MINOR; if (ddi_create_minor_node(vdc->dip, "wd,raw", S_IFCHR, VD_MAKE_DEV(vdc->instance, VD_EFI_WD_SLICE), DDI_NT_BLOCK, 0) != DDI_SUCCESS) { cmn_err(CE_NOTE, "[%d] Couldn't add block node 'wd,raw'", vdc->instance); return (EIO); } return (0); } static int vdc_create_device_nodes_vtoc(vdc_t *vdc) { ddi_remove_minor_node(vdc->dip, "wd"); ddi_remove_minor_node(vdc->dip, "wd,raw"); if (ddi_create_minor_node(vdc->dip, "h", S_IFBLK, VD_MAKE_DEV(vdc->instance, VD_EFI_WD_SLICE), DDI_NT_BLOCK, 0) != DDI_SUCCESS) { cmn_err(CE_NOTE, "[%d] Couldn't add block node 'h'", vdc->instance); return (EIO); } /* if any device node is created we set this flag */ vdc->initialized |= VDC_MINOR; if (ddi_create_minor_node(vdc->dip, "h,raw", S_IFCHR, VD_MAKE_DEV(vdc->instance, VD_EFI_WD_SLICE), DDI_NT_BLOCK, 0) != DDI_SUCCESS) { cmn_err(CE_NOTE, "[%d] Couldn't add block node 'h,raw'", vdc->instance); return (EIO); } return (0); } /* * Function: * vdc_create_device_nodes * * Description: * This function creates the block and character device nodes under * /devices along with the node properties. It is called as part of * the attach(9E) of the instance during the handshake with vds after * vds has sent the attributes to vdc. * * If the device is of type VD_DISK_TYPE_SLICE then the minor node * of 2 is used in keeping with the Solaris convention that slice 2 * refers to a whole disk. Slices start at 'a' * * Parameters: * vdc - soft state pointer * * Return Values * 0 - Success * EIO - Failed to create node * EINVAL - Unknown type of disk exported */ static int vdc_create_device_nodes(vdc_t *vdc) { char name[sizeof ("s,raw")]; dev_info_t *dip = NULL; int instance, status; int num_slices = 1; int i; ASSERT(vdc != NULL); instance = vdc->instance; dip = vdc->dip; switch (vdc->vdisk_type) { case VD_DISK_TYPE_DISK: num_slices = V_NUMPAR; break; case VD_DISK_TYPE_SLICE: num_slices = 1; break; case VD_DISK_TYPE_UNK: default: return (EINVAL); } /* * Minor nodes are different for EFI disks: EFI disks do not have * a minor node 'g' for the minor number corresponding to slice * VD_EFI_WD_SLICE (slice 7) instead they have a minor node 'wd' * representing the whole disk. */ for (i = 0; i < num_slices; i++) { if (i == VD_EFI_WD_SLICE) { if (vdc->vdisk_label == VD_DISK_LABEL_EFI) status = vdc_create_device_nodes_efi(vdc); else status = vdc_create_device_nodes_vtoc(vdc); if (status != 0) return (status); continue; } (void) snprintf(name, sizeof (name), "%c", 'a' + i); if (ddi_create_minor_node(dip, name, S_IFBLK, VD_MAKE_DEV(instance, i), DDI_NT_BLOCK, 0) != DDI_SUCCESS) { cmn_err(CE_NOTE, "[%d] Couldn't add block node '%s'", instance, name); return (EIO); } /* if any device node is created we set this flag */ vdc->initialized |= VDC_MINOR; (void) snprintf(name, sizeof (name), "%c%s", 'a' + i, ",raw"); if (ddi_create_minor_node(dip, name, S_IFCHR, VD_MAKE_DEV(instance, i), DDI_NT_BLOCK, 0) != DDI_SUCCESS) { cmn_err(CE_NOTE, "[%d] Couldn't add raw node '%s'", instance, name); return (EIO); } } return (0); } /* * Function: * vdc_create_device_nodes_props * * Description: * This function creates the block and character device nodes under * /devices along with the node properties. It is called as part of * the attach(9E) of the instance during the handshake with vds after * vds has sent the attributes to vdc. * * Parameters: * vdc - soft state pointer * * Return Values * 0 - Success * EIO - Failed to create device node property * EINVAL - Unknown type of disk exported */ static int vdc_create_device_nodes_props(vdc_t *vdc) { dev_info_t *dip = NULL; int instance; int num_slices = 1; int64_t size = 0; dev_t dev; int rv; int i; ASSERT(vdc != NULL); ASSERT(vdc->vtoc != NULL); instance = vdc->instance; dip = vdc->dip; switch (vdc->vdisk_type) { case VD_DISK_TYPE_DISK: num_slices = V_NUMPAR; break; case VD_DISK_TYPE_SLICE: num_slices = 1; break; case VD_DISK_TYPE_UNK: default: return (EINVAL); } if (vdc->vdisk_label == VD_DISK_LABEL_UNK) { /* remove all properties */ for (i = 0; i < num_slices; i++) { dev = makedevice(ddi_driver_major(dip), VD_MAKE_DEV(instance, i)); (void) ddi_prop_remove(dev, dip, VDC_SIZE_PROP_NAME); (void) ddi_prop_remove(dev, dip, VDC_NBLOCKS_PROP_NAME); } return (0); } for (i = 0; i < num_slices; i++) { dev = makedevice(ddi_driver_major(dip), VD_MAKE_DEV(instance, i)); size = vdc->vtoc->v_part[i].p_size * vdc->vtoc->v_sectorsz; DMSG(vdc, 0, "[%d] sz %ld (%ld Mb) p_size %lx\n", instance, size, size / (1024 * 1024), vdc->vtoc->v_part[i].p_size); rv = ddi_prop_update_int64(dev, dip, VDC_SIZE_PROP_NAME, size); if (rv != DDI_PROP_SUCCESS) { cmn_err(CE_NOTE, "[%d] Couldn't add '%s' prop of [%ld]", instance, VDC_SIZE_PROP_NAME, size); return (EIO); } rv = ddi_prop_update_int64(dev, dip, VDC_NBLOCKS_PROP_NAME, lbtodb(size)); if (rv != DDI_PROP_SUCCESS) { cmn_err(CE_NOTE, "[%d] Couldn't add '%s' prop [%llu]", instance, VDC_NBLOCKS_PROP_NAME, lbtodb(size)); return (EIO); } } return (0); } /* * Function: * vdc_is_opened * * Description: * This function checks if any slice of a given virtual disk is * currently opened. * * Parameters: * vdc - soft state pointer * * Return Values * B_TRUE - at least one slice is opened. * B_FALSE - no slice is opened. */ static boolean_t vdc_is_opened(vdc_t *vdc) { int i, nslices; switch (vdc->vdisk_type) { case VD_DISK_TYPE_DISK: nslices = V_NUMPAR; break; case VD_DISK_TYPE_SLICE: nslices = 1; break; case VD_DISK_TYPE_UNK: default: ASSERT(0); } /* check if there's any layered open */ for (i = 0; i < nslices; i++) { if (vdc->open_lyr[i] > 0) return (B_TRUE); } /* check if there is any other kind of open */ for (i = 0; i < OTYPCNT; i++) { if (vdc->open[i] != 0) return (B_TRUE); } return (B_FALSE); } static int vdc_mark_opened(vdc_t *vdc, int slice, int flag, int otyp) { uint8_t slicemask; int i; ASSERT(otyp < OTYPCNT); ASSERT(slice < V_NUMPAR); ASSERT(MUTEX_HELD(&vdc->lock)); slicemask = 1 << slice; /* check if slice is already exclusively opened */ if (vdc->open_excl & slicemask) return (EBUSY); /* if open exclusive, check if slice is already opened */ if (flag & FEXCL) { if (vdc->open_lyr[slice] > 0) return (EBUSY); for (i = 0; i < OTYPCNT; i++) { if (vdc->open[i] & slicemask) return (EBUSY); } vdc->open_excl |= slicemask; } /* mark slice as opened */ if (otyp == OTYP_LYR) { vdc->open_lyr[slice]++; } else { vdc->open[otyp] |= slicemask; } return (0); } static void vdc_mark_closed(vdc_t *vdc, int slice, int flag, int otyp) { uint8_t slicemask; ASSERT(otyp < OTYPCNT); ASSERT(slice < V_NUMPAR); ASSERT(MUTEX_HELD(&vdc->lock)); slicemask = 1 << slice; if (otyp == OTYP_LYR) { ASSERT(vdc->open_lyr[slice] > 0); vdc->open_lyr[slice]--; } else { vdc->open[otyp] &= ~slicemask; } if (flag & FEXCL) vdc->open_excl &= ~slicemask; } static int vdc_open(dev_t *dev, int flag, int otyp, cred_t *cred) { _NOTE(ARGUNUSED(cred)) int instance; int slice, status = 0; vdc_t *vdc; ASSERT(dev != NULL); instance = VDCUNIT(*dev); if (otyp >= OTYPCNT) return (EINVAL); if ((vdc = ddi_get_soft_state(vdc_state, instance)) == NULL) { cmn_err(CE_NOTE, "[%d] Couldn't get state structure", instance); return (ENXIO); } DMSG(vdc, 0, "minor = %d flag = %x, otyp = %x\n", getminor(*dev), flag, otyp); slice = VDCPART(*dev); mutex_enter(&vdc->lock); status = vdc_mark_opened(vdc, slice, flag, otyp); if (status != 0) { mutex_exit(&vdc->lock); return (status); } if (flag & (FNDELAY | FNONBLOCK)) { /* don't resubmit a validate request if there's already one */ if (vdc->validate_pending > 0) { mutex_exit(&vdc->lock); return (0); } /* call vdc_validate() asynchronously to avoid blocking */ if (taskq_dispatch(system_taskq, vdc_validate_task, (void *)vdc, TQ_NOSLEEP) == NULL) { vdc_mark_closed(vdc, slice, flag, otyp); mutex_exit(&vdc->lock); return (ENXIO); } vdc->validate_pending++; mutex_exit(&vdc->lock); return (0); } mutex_exit(&vdc->lock); vdc_validate(vdc); mutex_enter(&vdc->lock); if (vdc->vdisk_label == VD_DISK_LABEL_UNK || vdc->vtoc->v_part[slice].p_size == 0) { vdc_mark_closed(vdc, slice, flag, otyp); status = EIO; } mutex_exit(&vdc->lock); return (status); } static int vdc_close(dev_t dev, int flag, int otyp, cred_t *cred) { _NOTE(ARGUNUSED(cred)) int instance; int slice; int rv, rval; vdc_t *vdc; instance = VDCUNIT(dev); if (otyp >= OTYPCNT) return (EINVAL); if ((vdc = ddi_get_soft_state(vdc_state, instance)) == NULL) { cmn_err(CE_NOTE, "[%d] Couldn't get state structure", instance); return (ENXIO); } DMSG(vdc, 0, "[%d] flag = %x, otyp = %x\n", instance, flag, otyp); slice = VDCPART(dev); /* * Attempt to flush the W$ on a close operation. If this is * not a supported IOCTL command or the backing device is read-only * do not fail the close operation. */ rv = vd_process_ioctl(dev, DKIOCFLUSHWRITECACHE, NULL, FKIOCTL, &rval); if (rv != 0 && rv != ENOTSUP && rv != ENOTTY && rv != EROFS) { DMSG(vdc, 0, "[%d] flush failed with error %d on close\n", instance, rv); return (EIO); } mutex_enter(&vdc->lock); vdc_mark_closed(vdc, slice, flag, otyp); mutex_exit(&vdc->lock); return (0); } static int vdc_ioctl(dev_t dev, int cmd, intptr_t arg, int mode, cred_t *credp, int *rvalp) { _NOTE(ARGUNUSED(credp)) return (vd_process_ioctl(dev, cmd, (caddr_t)arg, mode, rvalp)); } static int vdc_print(dev_t dev, char *str) { cmn_err(CE_NOTE, "vdc%d: %s", VDCUNIT(dev), str); return (0); } static int vdc_dump(dev_t dev, caddr_t addr, daddr_t blkno, int nblk) { int rv; size_t nbytes = nblk * DEV_BSIZE; int instance = VDCUNIT(dev); vdc_t *vdc = NULL; if ((vdc = ddi_get_soft_state(vdc_state, instance)) == NULL) { cmn_err(CE_NOTE, "[%d] Couldn't get state structure", instance); return (ENXIO); } DMSG(vdc, 2, "[%d] dump %ld bytes at block 0x%lx : addr=0x%p\n", instance, nbytes, blkno, (void *)addr); rv = vdc_send_request(vdc, VD_OP_BWRITE, addr, nbytes, VDCPART(dev), blkno, CB_STRATEGY, 0, VIO_write_dir); if (rv) { DMSG(vdc, 0, "Failed to do a disk dump (err=%d)\n", rv); return (rv); } if (ddi_in_panic()) (void) vdc_drain_response(vdc); DMSG(vdc, 0, "[%d] End\n", instance); return (0); } /* -------------------------------------------------------------------------- */ /* * Disk access routines * */ /* * vdc_strategy() * * Return Value: * 0: As per strategy(9E), the strategy() function must return 0 * [ bioerror(9f) sets b_flags to the proper error code ] */ static int vdc_strategy(struct buf *buf) { int rv = -1; vdc_t *vdc = NULL; int instance = VDCUNIT(buf->b_edev); int op = (buf->b_flags & B_READ) ? VD_OP_BREAD : VD_OP_BWRITE; int slice; if ((vdc = ddi_get_soft_state(vdc_state, instance)) == NULL) { cmn_err(CE_NOTE, "[%d] Couldn't get state structure", instance); bioerror(buf, ENXIO); biodone(buf); return (0); } DMSG(vdc, 2, "[%d] %s %ld bytes at block %llx : b_addr=0x%p\n", instance, (buf->b_flags & B_READ) ? "Read" : "Write", buf->b_bcount, buf->b_lblkno, (void *)buf->b_un.b_addr); DTRACE_IO2(vstart, buf_t *, buf, vdc_t *, vdc); bp_mapin(buf); if ((long)buf->b_private == VD_SLICE_NONE) { /* I/O using an absolute disk offset */ slice = VD_SLICE_NONE; } else { slice = VDCPART(buf->b_edev); } rv = vdc_send_request(vdc, op, (caddr_t)buf->b_un.b_addr, buf->b_bcount, slice, buf->b_lblkno, CB_STRATEGY, buf, (op == VD_OP_BREAD) ? VIO_read_dir : VIO_write_dir); /* * If the request was successfully sent, the strategy call returns and * the ACK handler calls the bioxxx functions when the vDisk server is * done. */ if (rv) { DMSG(vdc, 0, "Failed to read/write (err=%d)\n", rv); bioerror(buf, rv); biodone(buf); } return (0); } /* * Function: * vdc_min * * Description: * Routine to limit the size of a data transfer. Used in * conjunction with physio(9F). * * Arguments: * bp - pointer to the indicated buf(9S) struct. * */ static void vdc_min(struct buf *bufp) { vdc_t *vdc = NULL; int instance = VDCUNIT(bufp->b_edev); vdc = ddi_get_soft_state(vdc_state, instance); VERIFY(vdc != NULL); if (bufp->b_bcount > (vdc->max_xfer_sz * vdc->block_size)) { bufp->b_bcount = vdc->max_xfer_sz * vdc->block_size; } } static int vdc_read(dev_t dev, struct uio *uio, cred_t *cred) { _NOTE(ARGUNUSED(cred)) DMSGX(1, "[%d] Entered", VDCUNIT(dev)); return (physio(vdc_strategy, NULL, dev, B_READ, vdc_min, uio)); } static int vdc_write(dev_t dev, struct uio *uio, cred_t *cred) { _NOTE(ARGUNUSED(cred)) DMSGX(1, "[%d] Entered", VDCUNIT(dev)); return (physio(vdc_strategy, NULL, dev, B_WRITE, vdc_min, uio)); } static int vdc_aread(dev_t dev, struct aio_req *aio, cred_t *cred) { _NOTE(ARGUNUSED(cred)) DMSGX(1, "[%d] Entered", VDCUNIT(dev)); return (aphysio(vdc_strategy, anocancel, dev, B_READ, vdc_min, aio)); } static int vdc_awrite(dev_t dev, struct aio_req *aio, cred_t *cred) { _NOTE(ARGUNUSED(cred)) DMSGX(1, "[%d] Entered", VDCUNIT(dev)); return (aphysio(vdc_strategy, anocancel, dev, B_WRITE, vdc_min, aio)); } /* -------------------------------------------------------------------------- */ /* * Handshake support */ /* * Function: * vdc_init_ver_negotiation() * * Description: * * Arguments: * vdc - soft state pointer for this instance of the device driver. * * Return Code: * 0 - Success */ static int vdc_init_ver_negotiation(vdc_t *vdc, vio_ver_t ver) { vio_ver_msg_t pkt; size_t msglen = sizeof (pkt); int status = -1; ASSERT(vdc != NULL); ASSERT(mutex_owned(&vdc->lock)); DMSG(vdc, 0, "[%d] Entered.\n", vdc->instance); /* * set the Session ID to a unique value * (the lower 32 bits of the clock tick) */ vdc->session_id = ((uint32_t)gettick() & 0xffffffff); DMSG(vdc, 0, "[%d] Set SID to 0x%lx\n", vdc->instance, vdc->session_id); pkt.tag.vio_msgtype = VIO_TYPE_CTRL; pkt.tag.vio_subtype = VIO_SUBTYPE_INFO; pkt.tag.vio_subtype_env = VIO_VER_INFO; pkt.tag.vio_sid = vdc->session_id; pkt.dev_class = VDEV_DISK; pkt.ver_major = ver.major; pkt.ver_minor = ver.minor; status = vdc_send(vdc, (caddr_t)&pkt, &msglen); DMSG(vdc, 0, "[%d] Ver info sent (status = %d)\n", vdc->instance, status); if ((status != 0) || (msglen != sizeof (vio_ver_msg_t))) { DMSG(vdc, 0, "[%d] Failed to send Ver negotiation info: " "id(%lx) rv(%d) size(%ld)", vdc->instance, vdc->ldc_handle, status, msglen); if (msglen != sizeof (vio_ver_msg_t)) status = ENOMSG; } return (status); } /* * Function: * vdc_ver_negotiation() * * Description: * * Arguments: * vdcp - soft state pointer for this instance of the device driver. * * Return Code: * 0 - Success */ static int vdc_ver_negotiation(vdc_t *vdcp) { vio_msg_t vio_msg; int status; if (status = vdc_init_ver_negotiation(vdcp, vdc_version[0])) return (status); /* release lock and wait for response */ mutex_exit(&vdcp->lock); status = vdc_wait_for_response(vdcp, &vio_msg); mutex_enter(&vdcp->lock); if (status) { DMSG(vdcp, 0, "[%d] Failed waiting for Ver negotiation response, rv(%d)", vdcp->instance, status); return (status); } /* check type and sub_type ... */ if (vio_msg.tag.vio_msgtype != VIO_TYPE_CTRL || vio_msg.tag.vio_subtype == VIO_SUBTYPE_INFO) { DMSG(vdcp, 0, "[%d] Invalid ver negotiation response\n", vdcp->instance); return (EPROTO); } return (vdc_handle_ver_msg(vdcp, (vio_ver_msg_t *)&vio_msg)); } /* * Function: * vdc_init_attr_negotiation() * * Description: * * Arguments: * vdc - soft state pointer for this instance of the device driver. * * Return Code: * 0 - Success */ static int vdc_init_attr_negotiation(vdc_t *vdc) { vd_attr_msg_t pkt; size_t msglen = sizeof (pkt); int status; ASSERT(vdc != NULL); ASSERT(mutex_owned(&vdc->lock)); DMSG(vdc, 0, "[%d] entered\n", vdc->instance); /* fill in tag */ pkt.tag.vio_msgtype = VIO_TYPE_CTRL; pkt.tag.vio_subtype = VIO_SUBTYPE_INFO; pkt.tag.vio_subtype_env = VIO_ATTR_INFO; pkt.tag.vio_sid = vdc->session_id; /* fill in payload */ pkt.max_xfer_sz = vdc->max_xfer_sz; pkt.vdisk_block_size = vdc->block_size; pkt.xfer_mode = VIO_DRING_MODE; pkt.operations = 0; /* server will set bits of valid operations */ pkt.vdisk_type = 0; /* server will set to valid device type */ pkt.vdisk_media = 0; /* server will set to valid media type */ pkt.vdisk_size = 0; /* server will set to valid size */ status = vdc_send(vdc, (caddr_t)&pkt, &msglen); DMSG(vdc, 0, "Attr info sent (status = %d)\n", status); if ((status != 0) || (msglen != sizeof (vio_ver_msg_t))) { DMSG(vdc, 0, "[%d] Failed to send Attr negotiation info: " "id(%lx) rv(%d) size(%ld)", vdc->instance, vdc->ldc_handle, status, msglen); if (msglen != sizeof (vio_ver_msg_t)) status = ENOMSG; } return (status); } /* * Function: * vdc_attr_negotiation() * * Description: * * Arguments: * vdc - soft state pointer for this instance of the device driver. * * Return Code: * 0 - Success */ static int vdc_attr_negotiation(vdc_t *vdcp) { int status; vio_msg_t vio_msg; if (status = vdc_init_attr_negotiation(vdcp)) return (status); /* release lock and wait for response */ mutex_exit(&vdcp->lock); status = vdc_wait_for_response(vdcp, &vio_msg); mutex_enter(&vdcp->lock); if (status) { DMSG(vdcp, 0, "[%d] Failed waiting for Attr negotiation response, rv(%d)", vdcp->instance, status); return (status); } /* check type and sub_type ... */ if (vio_msg.tag.vio_msgtype != VIO_TYPE_CTRL || vio_msg.tag.vio_subtype == VIO_SUBTYPE_INFO) { DMSG(vdcp, 0, "[%d] Invalid attr negotiation response\n", vdcp->instance); return (EPROTO); } return (vdc_handle_attr_msg(vdcp, (vd_attr_msg_t *)&vio_msg)); } /* * Function: * vdc_init_dring_negotiate() * * Description: * * Arguments: * vdc - soft state pointer for this instance of the device driver. * * Return Code: * 0 - Success */ static int vdc_init_dring_negotiate(vdc_t *vdc) { vio_dring_reg_msg_t pkt; size_t msglen = sizeof (pkt); int status = -1; int retry; int nretries = 10; ASSERT(vdc != NULL); ASSERT(mutex_owned(&vdc->lock)); for (retry = 0; retry < nretries; retry++) { status = vdc_init_descriptor_ring(vdc); if (status != EAGAIN) break; drv_usecwait(vdc_min_timeout_ldc); } if (status != 0) { DMSG(vdc, 0, "[%d] Failed to init DRing (status = %d)\n", vdc->instance, status); return (status); } DMSG(vdc, 0, "[%d] Init of descriptor ring completed (status = %d)\n", vdc->instance, status); /* fill in tag */ pkt.tag.vio_msgtype = VIO_TYPE_CTRL; pkt.tag.vio_subtype = VIO_SUBTYPE_INFO; pkt.tag.vio_subtype_env = VIO_DRING_REG; pkt.tag.vio_sid = vdc->session_id; /* fill in payload */ pkt.dring_ident = 0; pkt.num_descriptors = vdc->dring_len; pkt.descriptor_size = vdc->dring_entry_size; pkt.options = (VIO_TX_DRING | VIO_RX_DRING); pkt.ncookies = vdc->dring_cookie_count; pkt.cookie[0] = vdc->dring_cookie[0]; /* for now just one cookie */ status = vdc_send(vdc, (caddr_t)&pkt, &msglen); if (status != 0) { DMSG(vdc, 0, "[%d] Failed to register DRing (err = %d)", vdc->instance, status); } return (status); } /* * Function: * vdc_dring_negotiation() * * Description: * * Arguments: * vdc - soft state pointer for this instance of the device driver. * * Return Code: * 0 - Success */ static int vdc_dring_negotiation(vdc_t *vdcp) { int status; vio_msg_t vio_msg; if (status = vdc_init_dring_negotiate(vdcp)) return (status); /* release lock and wait for response */ mutex_exit(&vdcp->lock); status = vdc_wait_for_response(vdcp, &vio_msg); mutex_enter(&vdcp->lock); if (status) { DMSG(vdcp, 0, "[%d] Failed waiting for Dring negotiation response," " rv(%d)", vdcp->instance, status); return (status); } /* check type and sub_type ... */ if (vio_msg.tag.vio_msgtype != VIO_TYPE_CTRL || vio_msg.tag.vio_subtype == VIO_SUBTYPE_INFO) { DMSG(vdcp, 0, "[%d] Invalid Dring negotiation response\n", vdcp->instance); return (EPROTO); } return (vdc_handle_dring_reg_msg(vdcp, (vio_dring_reg_msg_t *)&vio_msg)); } /* * Function: * vdc_send_rdx() * * Description: * * Arguments: * vdc - soft state pointer for this instance of the device driver. * * Return Code: * 0 - Success */ static int vdc_send_rdx(vdc_t *vdcp) { vio_msg_t msg; size_t msglen = sizeof (vio_msg_t); int status; /* * Send an RDX message to vds to indicate we are ready * to send data */ msg.tag.vio_msgtype = VIO_TYPE_CTRL; msg.tag.vio_subtype = VIO_SUBTYPE_INFO; msg.tag.vio_subtype_env = VIO_RDX; msg.tag.vio_sid = vdcp->session_id; status = vdc_send(vdcp, (caddr_t)&msg, &msglen); if (status != 0) { DMSG(vdcp, 0, "[%d] Failed to send RDX message (%d)", vdcp->instance, status); } return (status); } /* * Function: * vdc_handle_rdx() * * Description: * * Arguments: * vdc - soft state pointer for this instance of the device driver. * msgp - received msg * * Return Code: * 0 - Success */ static int vdc_handle_rdx(vdc_t *vdcp, vio_rdx_msg_t *msgp) { _NOTE(ARGUNUSED(vdcp)) _NOTE(ARGUNUSED(msgp)) ASSERT(msgp->tag.vio_msgtype == VIO_TYPE_CTRL); ASSERT(msgp->tag.vio_subtype == VIO_SUBTYPE_ACK); ASSERT(msgp->tag.vio_subtype_env == VIO_RDX); DMSG(vdcp, 1, "[%d] Got an RDX msg", vdcp->instance); return (0); } /* * Function: * vdc_rdx_exchange() * * Description: * * Arguments: * vdc - soft state pointer for this instance of the device driver. * * Return Code: * 0 - Success */ static int vdc_rdx_exchange(vdc_t *vdcp) { int status; vio_msg_t vio_msg; if (status = vdc_send_rdx(vdcp)) return (status); /* release lock and wait for response */ mutex_exit(&vdcp->lock); status = vdc_wait_for_response(vdcp, &vio_msg); mutex_enter(&vdcp->lock); if (status) { DMSG(vdcp, 0, "[%d] Failed waiting for RDX response, rv(%d)", vdcp->instance, status); return (status); } /* check type and sub_type ... */ if (vio_msg.tag.vio_msgtype != VIO_TYPE_CTRL || vio_msg.tag.vio_subtype != VIO_SUBTYPE_ACK) { DMSG(vdcp, 0, "[%d] Invalid RDX response\n", vdcp->instance); return (EPROTO); } return (vdc_handle_rdx(vdcp, (vio_rdx_msg_t *)&vio_msg)); } /* -------------------------------------------------------------------------- */ /* * LDC helper routines */ static int vdc_recv(vdc_t *vdc, vio_msg_t *msgp, size_t *nbytesp) { int status; boolean_t q_has_pkts = B_FALSE; uint64_t delay_time; size_t len; mutex_enter(&vdc->read_lock); if (vdc->read_state == VDC_READ_IDLE) vdc->read_state = VDC_READ_WAITING; while (vdc->read_state != VDC_READ_PENDING) { /* detect if the connection has been reset */ if (vdc->read_state == VDC_READ_RESET) { status = ECONNRESET; goto done; } cv_wait(&vdc->read_cv, &vdc->read_lock); } /* * Until we get a blocking ldc read we have to retry * until the entire LDC message has arrived before * ldc_read() will succeed. Note we also bail out if * the channel is reset or goes away. */ delay_time = vdc_ldc_read_init_delay; loop: len = *nbytesp; status = ldc_read(vdc->ldc_handle, (caddr_t)msgp, &len); switch (status) { case EAGAIN: delay_time *= 2; if (delay_time >= vdc_ldc_read_max_delay) delay_time = vdc_ldc_read_max_delay; delay(delay_time); goto loop; case 0: if (len == 0) { DMSG(vdc, 1, "[%d] ldc_read returned 0 bytes with " "no error!\n", vdc->instance); goto loop; } *nbytesp = len; /* * If there are pending messages, leave the * read state as pending. Otherwise, set the state * back to idle. */ status = ldc_chkq(vdc->ldc_handle, &q_has_pkts); if (status == 0 && !q_has_pkts) vdc->read_state = VDC_READ_IDLE; break; default: DMSG(vdc, 0, "ldc_read returned %d\n", status); break; } done: mutex_exit(&vdc->read_lock); return (status); } #ifdef DEBUG void vdc_decode_tag(vdc_t *vdcp, vio_msg_t *msg) { char *ms, *ss, *ses; switch (msg->tag.vio_msgtype) { #define Q(_s) case _s : ms = #_s; break; Q(VIO_TYPE_CTRL) Q(VIO_TYPE_DATA) Q(VIO_TYPE_ERR) #undef Q default: ms = "unknown"; break; } switch (msg->tag.vio_subtype) { #define Q(_s) case _s : ss = #_s; break; Q(VIO_SUBTYPE_INFO) Q(VIO_SUBTYPE_ACK) Q(VIO_SUBTYPE_NACK) #undef Q default: ss = "unknown"; break; } switch (msg->tag.vio_subtype_env) { #define Q(_s) case _s : ses = #_s; break; Q(VIO_VER_INFO) Q(VIO_ATTR_INFO) Q(VIO_DRING_REG) Q(VIO_DRING_UNREG) Q(VIO_RDX) Q(VIO_PKT_DATA) Q(VIO_DESC_DATA) Q(VIO_DRING_DATA) #undef Q default: ses = "unknown"; break; } DMSG(vdcp, 3, "(%x/%x/%x) message : (%s/%s/%s)\n", msg->tag.vio_msgtype, msg->tag.vio_subtype, msg->tag.vio_subtype_env, ms, ss, ses); } #endif /* * Function: * vdc_send() * * Description: * The function encapsulates the call to write a message using LDC. * If LDC indicates that the call failed due to the queue being full, * we retry the ldc_write(), otherwise we return the error returned by LDC. * * Arguments: * ldc_handle - LDC handle for the channel this instance of vdc uses * pkt - address of LDC message to be sent * msglen - the size of the message being sent. When the function * returns, this contains the number of bytes written. * * Return Code: * 0 - Success. * EINVAL - pkt or msglen were NULL * ECONNRESET - The connection was not up. * EWOULDBLOCK - LDC queue is full * xxx - other error codes returned by ldc_write */ static int vdc_send(vdc_t *vdc, caddr_t pkt, size_t *msglen) { size_t size = 0; int status = 0; clock_t delay_ticks; ASSERT(vdc != NULL); ASSERT(mutex_owned(&vdc->lock)); ASSERT(msglen != NULL); ASSERT(*msglen != 0); #ifdef DEBUG vdc_decode_tag(vdc, (vio_msg_t *)(uintptr_t)pkt); #endif /* * Wait indefinitely to send if channel * is busy, but bail out if we succeed or * if the channel closes or is reset. */ delay_ticks = vdc_hz_min_ldc_delay; do { size = *msglen; status = ldc_write(vdc->ldc_handle, pkt, &size); if (status == EWOULDBLOCK) { delay(delay_ticks); /* geometric backoff */ delay_ticks *= 2; if (delay_ticks > vdc_hz_max_ldc_delay) delay_ticks = vdc_hz_max_ldc_delay; } } while (status == EWOULDBLOCK); /* if LDC had serious issues --- reset vdc state */ if (status == EIO || status == ECONNRESET) { /* LDC had serious issues --- reset vdc state */ mutex_enter(&vdc->read_lock); if ((vdc->read_state == VDC_READ_WAITING) || (vdc->read_state == VDC_READ_RESET)) cv_signal(&vdc->read_cv); vdc->read_state = VDC_READ_RESET; mutex_exit(&vdc->read_lock); /* wake up any waiters in the reset thread */ if (vdc->state == VDC_STATE_INIT_WAITING) { DMSG(vdc, 0, "[%d] write reset - " "vdc is resetting ..\n", vdc->instance); vdc->state = VDC_STATE_RESETTING; cv_signal(&vdc->initwait_cv); } return (ECONNRESET); } /* return the last size written */ *msglen = size; return (status); } /* * Function: * vdc_get_md_node * * Description: * Get the MD, the device node and the port node for the given * disk instance. The caller is responsible for cleaning up the * reference to the returned MD (mdpp) by calling md_fini_handle(). * * Arguments: * dip - dev info pointer for this instance of the device driver. * mdpp - the returned MD. * vd_nodep - the returned device node. * vd_portp - the returned port node. The returned port node is NULL * if no port node is found. * * Return Code: * 0 - Success. * ENOENT - Expected node or property did not exist. * ENXIO - Unexpected error communicating with MD framework */ static int vdc_get_md_node(dev_info_t *dip, md_t **mdpp, mde_cookie_t *vd_nodep, mde_cookie_t *vd_portp) { int status = ENOENT; char *node_name = NULL; md_t *mdp = NULL; int num_nodes; int num_vdevs; int num_vports; mde_cookie_t rootnode; mde_cookie_t *listp = NULL; boolean_t found_inst = B_FALSE; int listsz; int idx; uint64_t md_inst; int obp_inst; int instance = ddi_get_instance(dip); /* * Get the OBP instance number for comparison with the MD instance * * The "cfg-handle" property of a vdc node in an MD contains the MD's * notion of "instance", or unique identifier, for that node; OBP * stores the value of the "cfg-handle" MD property as the value of * the "reg" property on the node in the device tree it builds from * the MD and passes to Solaris. Thus, we look up the devinfo node's * "reg" property value to uniquely identify this device instance. * If the "reg" property cannot be found, the device tree state is * presumably so broken that there is no point in continuing. */ if (!ddi_prop_exists(DDI_DEV_T_ANY, dip, DDI_PROP_DONTPASS, OBP_REG)) { cmn_err(CE_WARN, "'%s' property does not exist", OBP_REG); return (ENOENT); } obp_inst = ddi_prop_get_int(DDI_DEV_T_ANY, dip, DDI_PROP_DONTPASS, OBP_REG, -1); DMSGX(1, "[%d] OBP inst=%d\n", instance, obp_inst); /* * We now walk the MD nodes to find the node for this vdisk. */ if ((mdp = md_get_handle()) == NULL) { cmn_err(CE_WARN, "unable to init machine description"); return (ENXIO); } num_nodes = md_node_count(mdp); ASSERT(num_nodes > 0); listsz = num_nodes * sizeof (mde_cookie_t); /* allocate memory for nodes */ listp = kmem_zalloc(listsz, KM_SLEEP); rootnode = md_root_node(mdp); ASSERT(rootnode != MDE_INVAL_ELEM_COOKIE); /* * Search for all the virtual devices, we will then check to see which * ones are disk nodes. */ num_vdevs = md_scan_dag(mdp, rootnode, md_find_name(mdp, VDC_MD_VDEV_NAME), md_find_name(mdp, "fwd"), listp); if (num_vdevs <= 0) { cmn_err(CE_NOTE, "No '%s' node found", VDC_MD_VDEV_NAME); status = ENOENT; goto done; } DMSGX(1, "[%d] num_vdevs=%d\n", instance, num_vdevs); for (idx = 0; idx < num_vdevs; idx++) { status = md_get_prop_str(mdp, listp[idx], "name", &node_name); if ((status != 0) || (node_name == NULL)) { cmn_err(CE_NOTE, "Unable to get name of node type '%s'" ": err %d", VDC_MD_VDEV_NAME, status); continue; } DMSGX(1, "[%d] Found node '%s'\n", instance, node_name); if (strcmp(VDC_MD_DISK_NAME, node_name) == 0) { status = md_get_prop_val(mdp, listp[idx], VDC_MD_CFG_HDL, &md_inst); DMSGX(1, "[%d] vdc inst in MD=%lx\n", instance, md_inst); if ((status == 0) && (md_inst == obp_inst)) { found_inst = B_TRUE; break; } } } if (!found_inst) { DMSGX(0, "Unable to find correct '%s' node", VDC_MD_DISK_NAME); status = ENOENT; goto done; } DMSGX(0, "[%d] MD inst=%lx\n", instance, md_inst); *vd_nodep = listp[idx]; *mdpp = mdp; num_vports = md_scan_dag(mdp, *vd_nodep, md_find_name(mdp, VDC_MD_PORT_NAME), md_find_name(mdp, "fwd"), listp); if (num_vports != 1) { DMSGX(0, "Expected 1 '%s' node for '%s' port, found %d\n", VDC_MD_PORT_NAME, VDC_MD_VDEV_NAME, num_vports); } *vd_portp = (num_vports == 0)? NULL: listp[0]; done: kmem_free(listp, listsz); return (status); } /* * Function: * vdc_get_ldc_id() * * Description: * This function gets the 'ldc-id' for this particular instance of vdc. * The id returned is the guest domain channel endpoint LDC uses for * communication with vds. * * Arguments: * mdp - pointer to the machine description. * vd_node - the vdisk element from the MD. * ldc_id - pointer to variable used to return the 'ldc-id' found. * * Return Code: * 0 - Success. * ENOENT - Expected node or property did not exist. */ static int vdc_get_ldc_id(md_t *mdp, mde_cookie_t vd_node, uint64_t *ldc_id) { mde_cookie_t *chanp = NULL; int listsz; int num_chans; int num_nodes; int status = 0; num_nodes = md_node_count(mdp); ASSERT(num_nodes > 0); listsz = num_nodes * sizeof (mde_cookie_t); /* allocate memory for nodes */ chanp = kmem_zalloc(listsz, KM_SLEEP); /* get the channels for this node */ num_chans = md_scan_dag(mdp, vd_node, md_find_name(mdp, VDC_MD_CHAN_NAME), md_find_name(mdp, "fwd"), chanp); /* expecting at least one channel */ if (num_chans <= 0) { cmn_err(CE_NOTE, "No '%s' node for '%s' port", VDC_MD_CHAN_NAME, VDC_MD_VDEV_NAME); status = ENOENT; goto done; } else if (num_chans != 1) { DMSGX(0, "Expected 1 '%s' node for '%s' port, found %d\n", VDC_MD_CHAN_NAME, VDC_MD_VDEV_NAME, num_chans); } /* * We use the first channel found (index 0), irrespective of how * many are there in total. */ if (md_get_prop_val(mdp, chanp[0], VDC_MD_ID, ldc_id) != 0) { cmn_err(CE_NOTE, "Channel '%s' property not found", VDC_MD_ID); status = ENOENT; } done: kmem_free(chanp, listsz); return (status); } static int vdc_do_ldc_up(vdc_t *vdc) { int status; ldc_status_t ldc_state; DMSG(vdc, 0, "[%d] Bringing up channel %lx\n", vdc->instance, vdc->ldc_id); if (vdc->lifecycle == VDC_LC_DETACHING) return (EINVAL); if ((status = ldc_up(vdc->ldc_handle)) != 0) { switch (status) { case ECONNREFUSED: /* listener not ready at other end */ DMSG(vdc, 0, "[%d] ldc_up(%lx,...) return %d\n", vdc->instance, vdc->ldc_id, status); status = 0; break; default: DMSG(vdc, 0, "[%d] Failed to bring up LDC: " "channel=%ld, err=%d", vdc->instance, vdc->ldc_id, status); break; } } if (ldc_status(vdc->ldc_handle, &ldc_state) == 0) { vdc->ldc_state = ldc_state; if (ldc_state == LDC_UP) { DMSG(vdc, 0, "[%d] LDC channel already up\n", vdc->instance); vdc->seq_num = 1; vdc->seq_num_reply = 0; } } return (status); } /* * Function: * vdc_terminate_ldc() * * Description: * * Arguments: * vdc - soft state pointer for this instance of the device driver. * * Return Code: * None */ static void vdc_terminate_ldc(vdc_t *vdc) { int instance = ddi_get_instance(vdc->dip); ASSERT(vdc != NULL); ASSERT(mutex_owned(&vdc->lock)); DMSG(vdc, 0, "[%d] initialized=%x\n", instance, vdc->initialized); if (vdc->initialized & VDC_LDC_OPEN) { DMSG(vdc, 0, "[%d] ldc_close()\n", instance); (void) ldc_close(vdc->ldc_handle); } if (vdc->initialized & VDC_LDC_CB) { DMSG(vdc, 0, "[%d] ldc_unreg_callback()\n", instance); (void) ldc_unreg_callback(vdc->ldc_handle); } if (vdc->initialized & VDC_LDC) { DMSG(vdc, 0, "[%d] ldc_fini()\n", instance); (void) ldc_fini(vdc->ldc_handle); vdc->ldc_handle = NULL; } vdc->initialized &= ~(VDC_LDC | VDC_LDC_CB | VDC_LDC_OPEN); } /* -------------------------------------------------------------------------- */ /* * Descriptor Ring helper routines */ /* * Function: * vdc_init_descriptor_ring() * * Description: * * Arguments: * vdc - soft state pointer for this instance of the device driver. * * Return Code: * 0 - Success */ static int vdc_init_descriptor_ring(vdc_t *vdc) { vd_dring_entry_t *dep = NULL; /* DRing Entry pointer */ int status = 0; int i; DMSG(vdc, 0, "[%d] initialized=%x\n", vdc->instance, vdc->initialized); ASSERT(vdc != NULL); ASSERT(mutex_owned(&vdc->lock)); ASSERT(vdc->ldc_handle != NULL); /* ensure we have enough room to store max sized block */ ASSERT(maxphys <= VD_MAX_BLOCK_SIZE); if ((vdc->initialized & VDC_DRING_INIT) == 0) { DMSG(vdc, 0, "[%d] ldc_mem_dring_create\n", vdc->instance); /* * Calculate the maximum block size we can transmit using one * Descriptor Ring entry from the attributes returned by the * vDisk server. This is subject to a minimum of 'maxphys' * as we do not have the capability to split requests over * multiple DRing entries. */ if ((vdc->max_xfer_sz * vdc->block_size) < maxphys) { DMSG(vdc, 0, "[%d] using minimum DRing size\n", vdc->instance); vdc->dring_max_cookies = maxphys / PAGESIZE; } else { vdc->dring_max_cookies = (vdc->max_xfer_sz * vdc->block_size) / PAGESIZE; } vdc->dring_entry_size = (sizeof (vd_dring_entry_t) + (sizeof (ldc_mem_cookie_t) * (vdc->dring_max_cookies - 1))); vdc->dring_len = VD_DRING_LEN; status = ldc_mem_dring_create(vdc->dring_len, vdc->dring_entry_size, &vdc->ldc_dring_hdl); if ((vdc->ldc_dring_hdl == NULL) || (status != 0)) { DMSG(vdc, 0, "[%d] Descriptor ring creation failed", vdc->instance); return (status); } vdc->initialized |= VDC_DRING_INIT; } if ((vdc->initialized & VDC_DRING_BOUND) == 0) { DMSG(vdc, 0, "[%d] ldc_mem_dring_bind\n", vdc->instance); vdc->dring_cookie = kmem_zalloc(sizeof (ldc_mem_cookie_t), KM_SLEEP); status = ldc_mem_dring_bind(vdc->ldc_handle, vdc->ldc_dring_hdl, LDC_SHADOW_MAP|LDC_DIRECT_MAP, LDC_MEM_RW, &vdc->dring_cookie[0], &vdc->dring_cookie_count); if (status != 0) { DMSG(vdc, 0, "[%d] Failed to bind descriptor ring " "(%lx) to channel (%lx) status=%d\n", vdc->instance, vdc->ldc_dring_hdl, vdc->ldc_handle, status); return (status); } ASSERT(vdc->dring_cookie_count == 1); vdc->initialized |= VDC_DRING_BOUND; } status = ldc_mem_dring_info(vdc->ldc_dring_hdl, &vdc->dring_mem_info); if (status != 0) { DMSG(vdc, 0, "[%d] Failed to get info for descriptor ring (%lx)\n", vdc->instance, vdc->ldc_dring_hdl); return (status); } if ((vdc->initialized & VDC_DRING_LOCAL) == 0) { DMSG(vdc, 0, "[%d] local dring\n", vdc->instance); /* Allocate the local copy of this dring */ vdc->local_dring = kmem_zalloc(vdc->dring_len * sizeof (vdc_local_desc_t), KM_SLEEP); vdc->initialized |= VDC_DRING_LOCAL; } /* * Mark all DRing entries as free and initialize the private * descriptor's memory handles. If any entry is initialized, * we need to free it later so we set the bit in 'initialized' * at the start. */ vdc->initialized |= VDC_DRING_ENTRY; for (i = 0; i < vdc->dring_len; i++) { dep = VDC_GET_DRING_ENTRY_PTR(vdc, i); dep->hdr.dstate = VIO_DESC_FREE; status = ldc_mem_alloc_handle(vdc->ldc_handle, &vdc->local_dring[i].desc_mhdl); if (status != 0) { DMSG(vdc, 0, "![%d] Failed to alloc mem handle for" " descriptor %d", vdc->instance, i); return (status); } vdc->local_dring[i].is_free = B_TRUE; vdc->local_dring[i].dep = dep; } /* Initialize the starting index */ vdc->dring_curr_idx = 0; return (status); } /* * Function: * vdc_destroy_descriptor_ring() * * Description: * * Arguments: * vdc - soft state pointer for this instance of the device driver. * * Return Code: * None */ static void vdc_destroy_descriptor_ring(vdc_t *vdc) { vdc_local_desc_t *ldep = NULL; /* Local Dring Entry Pointer */ ldc_mem_handle_t mhdl = NULL; ldc_mem_info_t minfo; int status = -1; int i; /* loop */ ASSERT(vdc != NULL); ASSERT(mutex_owned(&vdc->lock)); DMSG(vdc, 0, "[%d] Entered\n", vdc->instance); if (vdc->initialized & VDC_DRING_ENTRY) { DMSG(vdc, 0, "[%d] Removing Local DRing entries\n", vdc->instance); for (i = 0; i < vdc->dring_len; i++) { ldep = &vdc->local_dring[i]; mhdl = ldep->desc_mhdl; if (mhdl == NULL) continue; if ((status = ldc_mem_info(mhdl, &minfo)) != 0) { DMSG(vdc, 0, "ldc_mem_info returned an error: %d\n", status); /* * This must mean that the mem handle * is not valid. Clear it out so that * no one tries to use it. */ ldep->desc_mhdl = NULL; continue; } if (minfo.status == LDC_BOUND) { (void) ldc_mem_unbind_handle(mhdl); } (void) ldc_mem_free_handle(mhdl); ldep->desc_mhdl = NULL; } vdc->initialized &= ~VDC_DRING_ENTRY; } if (vdc->initialized & VDC_DRING_LOCAL) { DMSG(vdc, 0, "[%d] Freeing Local DRing\n", vdc->instance); kmem_free(vdc->local_dring, vdc->dring_len * sizeof (vdc_local_desc_t)); vdc->initialized &= ~VDC_DRING_LOCAL; } if (vdc->initialized & VDC_DRING_BOUND) { DMSG(vdc, 0, "[%d] Unbinding DRing\n", vdc->instance); status = ldc_mem_dring_unbind(vdc->ldc_dring_hdl); if (status == 0) { vdc->initialized &= ~VDC_DRING_BOUND; } else { DMSG(vdc, 0, "[%d] Error %d unbinding DRing %lx", vdc->instance, status, vdc->ldc_dring_hdl); } kmem_free(vdc->dring_cookie, sizeof (ldc_mem_cookie_t)); } if (vdc->initialized & VDC_DRING_INIT) { DMSG(vdc, 0, "[%d] Destroying DRing\n", vdc->instance); status = ldc_mem_dring_destroy(vdc->ldc_dring_hdl); if (status == 0) { vdc->ldc_dring_hdl = NULL; bzero(&vdc->dring_mem_info, sizeof (ldc_mem_info_t)); vdc->initialized &= ~VDC_DRING_INIT; } else { DMSG(vdc, 0, "[%d] Error %d destroying DRing (%lx)", vdc->instance, status, vdc->ldc_dring_hdl); } } } /* * Function: * vdc_map_to_shared_ring() * * Description: * Copy contents of the local descriptor to the shared * memory descriptor. * * Arguments: * vdcp - soft state pointer for this instance of the device driver. * idx - descriptor ring index * * Return Code: * None */ static int vdc_map_to_shared_dring(vdc_t *vdcp, int idx) { vdc_local_desc_t *ldep; vd_dring_entry_t *dep; int rv; ldep = &(vdcp->local_dring[idx]); /* for now leave in the old pop_mem_hdl stuff */ if (ldep->nbytes > 0) { rv = vdc_populate_mem_hdl(vdcp, ldep); if (rv) { DMSG(vdcp, 0, "[%d] Cannot populate mem handle\n", vdcp->instance); return (rv); } } /* * fill in the data details into the DRing */ dep = ldep->dep; ASSERT(dep != NULL); dep->payload.req_id = VDC_GET_NEXT_REQ_ID(vdcp); dep->payload.operation = ldep->operation; dep->payload.addr = ldep->offset; dep->payload.nbytes = ldep->nbytes; dep->payload.status = (uint32_t)-1; /* vds will set valid value */ dep->payload.slice = ldep->slice; dep->hdr.dstate = VIO_DESC_READY; dep->hdr.ack = 1; /* request an ACK for every message */ return (0); } /* * Function: * vdc_send_request * * Description: * This routine writes the data to be transmitted to vds into the * descriptor, notifies vds that the ring has been updated and * then waits for the request to be processed. * * Arguments: * vdcp - the soft state pointer * operation - operation we want vds to perform (VD_OP_XXX) * addr - address of data buf to be read/written. * nbytes - number of bytes to read/write * slice - the disk slice this request is for * offset - relative disk offset * cb_type - type of call - STRATEGY or SYNC * cb_arg - parameter to be sent to server (depends on VD_OP_XXX type) * . mode for ioctl(9e) * . LP64 diskaddr_t (block I/O) * dir - direction of operation (READ/WRITE/BOTH) * * Return Codes: * 0 * ENXIO */ static int vdc_send_request(vdc_t *vdcp, int operation, caddr_t addr, size_t nbytes, int slice, diskaddr_t offset, int cb_type, void *cb_arg, vio_desc_direction_t dir) { ASSERT(vdcp != NULL); ASSERT(slice == VD_SLICE_NONE || slice < V_NUMPAR); mutex_enter(&vdcp->lock); do { while (vdcp->state != VDC_STATE_RUNNING) { /* return error if detaching */ if (vdcp->state == VDC_STATE_DETACH) { mutex_exit(&vdcp->lock); return (ENXIO); } /* fail request if connection timeout is reached */ if (vdcp->ctimeout_reached) { mutex_exit(&vdcp->lock); return (EIO); } /* * If we are panicking and the disk is not ready then * we can't send any request because we can't complete * the handshake now. */ if (ddi_in_panic()) { mutex_exit(&vdcp->lock); return (EIO); } cv_wait(&vdcp->running_cv, &vdcp->lock); } } while (vdc_populate_descriptor(vdcp, operation, addr, nbytes, slice, offset, cb_type, cb_arg, dir)); mutex_exit(&vdcp->lock); return (0); } /* * Function: * vdc_populate_descriptor * * Description: * This routine writes the data to be transmitted to vds into the * descriptor, notifies vds that the ring has been updated and * then waits for the request to be processed. * * Arguments: * vdcp - the soft state pointer * operation - operation we want vds to perform (VD_OP_XXX) * addr - address of data buf to be read/written. * nbytes - number of bytes to read/write * slice - the disk slice this request is for * offset - relative disk offset * cb_type - type of call - STRATEGY or SYNC * cb_arg - parameter to be sent to server (depends on VD_OP_XXX type) * . mode for ioctl(9e) * . LP64 diskaddr_t (block I/O) * dir - direction of operation (READ/WRITE/BOTH) * * Return Codes: * 0 * EAGAIN * ECONNRESET * ENXIO */ static int vdc_populate_descriptor(vdc_t *vdcp, int operation, caddr_t addr, size_t nbytes, int slice, diskaddr_t offset, int cb_type, void *cb_arg, vio_desc_direction_t dir) { vdc_local_desc_t *local_dep = NULL; /* Local Dring Pointer */ int idx; /* Index of DRing entry used */ int next_idx; vio_dring_msg_t dmsg; size_t msglen; int rv; ASSERT(MUTEX_HELD(&vdcp->lock)); vdcp->threads_pending++; loop: DMSG(vdcp, 2, ": dring_curr_idx = %d\n", vdcp->dring_curr_idx); /* Get next available D-Ring entry */ idx = vdcp->dring_curr_idx; local_dep = &(vdcp->local_dring[idx]); if (!local_dep->is_free) { DMSG(vdcp, 2, "[%d]: dring full - waiting for space\n", vdcp->instance); cv_wait(&vdcp->dring_free_cv, &vdcp->lock); if (vdcp->state == VDC_STATE_RUNNING || vdcp->state == VDC_STATE_HANDLE_PENDING) { goto loop; } vdcp->threads_pending--; return (ECONNRESET); } next_idx = idx + 1; if (next_idx >= vdcp->dring_len) next_idx = 0; vdcp->dring_curr_idx = next_idx; ASSERT(local_dep->is_free); local_dep->operation = operation; local_dep->addr = addr; local_dep->nbytes = nbytes; local_dep->slice = slice; local_dep->offset = offset; local_dep->cb_type = cb_type; local_dep->cb_arg = cb_arg; local_dep->dir = dir; local_dep->is_free = B_FALSE; rv = vdc_map_to_shared_dring(vdcp, idx); if (rv) { DMSG(vdcp, 0, "[%d]: cannot bind memory - waiting ..\n", vdcp->instance); /* free the descriptor */ local_dep->is_free = B_TRUE; vdcp->dring_curr_idx = idx; cv_wait(&vdcp->membind_cv, &vdcp->lock); if (vdcp->state == VDC_STATE_RUNNING || vdcp->state == VDC_STATE_HANDLE_PENDING) { goto loop; } vdcp->threads_pending--; return (ECONNRESET); } /* * Send a msg with the DRing details to vds */ VIO_INIT_DRING_DATA_TAG(dmsg); VDC_INIT_DRING_DATA_MSG_IDS(dmsg, vdcp); dmsg.dring_ident = vdcp->dring_ident; dmsg.start_idx = idx; dmsg.end_idx = idx; vdcp->seq_num++; DTRACE_IO2(send, vio_dring_msg_t *, &dmsg, vdc_t *, vdcp); DMSG(vdcp, 2, "ident=0x%lx, st=%u, end=%u, seq=%ld\n", vdcp->dring_ident, dmsg.start_idx, dmsg.end_idx, dmsg.seq_num); /* * note we're still holding the lock here to * make sure the message goes out in order !!!... */ msglen = sizeof (dmsg); rv = vdc_send(vdcp, (caddr_t)&dmsg, &msglen); switch (rv) { case ECONNRESET: /* * vdc_send initiates the reset on failure. * Since the transaction has already been put * on the local dring, it will automatically get * retried when the channel is reset. Given that, * it is ok to just return success even though the * send failed. */ rv = 0; break; case 0: /* EOK */ DMSG(vdcp, 1, "sent via LDC: rv=%d\n", rv); break; default: goto cleanup_and_exit; } vdcp->threads_pending--; return (rv); cleanup_and_exit: DMSG(vdcp, 0, "unexpected error, rv=%d\n", rv); return (ENXIO); } /* * Function: * vdc_do_sync_op * * Description: * Wrapper around vdc_populate_descriptor that blocks until the * response to the message is available. * * Arguments: * vdcp - the soft state pointer * operation - operation we want vds to perform (VD_OP_XXX) * addr - address of data buf to be read/written. * nbytes - number of bytes to read/write * slice - the disk slice this request is for * offset - relative disk offset * cb_type - type of call - STRATEGY or SYNC * cb_arg - parameter to be sent to server (depends on VD_OP_XXX type) * . mode for ioctl(9e) * . LP64 diskaddr_t (block I/O) * dir - direction of operation (READ/WRITE/BOTH) * rconflict - check for reservation conflict in case of failure * * rconflict should be set to B_TRUE by most callers. Callers invoking the * VD_OP_SCSICMD operation can set rconflict to B_FALSE if they check the * result of a successful operation with vd_scsi_status(). * * Return Codes: * 0 * EAGAIN * EFAULT * ENXIO * EIO */ static int vdc_do_sync_op(vdc_t *vdcp, int operation, caddr_t addr, size_t nbytes, int slice, diskaddr_t offset, int cb_type, void *cb_arg, vio_desc_direction_t dir, boolean_t rconflict) { int status; vdc_io_t *vio; boolean_t check_resv_conflict = B_FALSE; ASSERT(cb_type == CB_SYNC); /* * Grab the lock, if blocked wait until the server * response causes us to wake up again. */ mutex_enter(&vdcp->lock); vdcp->sync_op_cnt++; while (vdcp->sync_op_blocked && vdcp->state != VDC_STATE_DETACH) cv_wait(&vdcp->sync_blocked_cv, &vdcp->lock); if (vdcp->state == VDC_STATE_DETACH) { cv_broadcast(&vdcp->sync_blocked_cv); vdcp->sync_op_cnt--; mutex_exit(&vdcp->lock); return (ENXIO); } /* now block anyone other thread entering after us */ vdcp->sync_op_blocked = B_TRUE; vdcp->sync_op_pending = B_TRUE; mutex_exit(&vdcp->lock); status = vdc_send_request(vdcp, operation, addr, nbytes, slice, offset, cb_type, cb_arg, dir); mutex_enter(&vdcp->lock); if (status != 0) { vdcp->sync_op_pending = B_FALSE; } else { /* * block until our transaction completes. * Also anyone else waiting also gets to go next. */ while (vdcp->sync_op_pending && vdcp->state != VDC_STATE_DETACH) cv_wait(&vdcp->sync_pending_cv, &vdcp->lock); DMSG(vdcp, 2, ": operation returned %d\n", vdcp->sync_op_status); if (vdcp->state == VDC_STATE_DETACH) { vdcp->sync_op_pending = B_FALSE; status = ENXIO; } else { status = vdcp->sync_op_status; if (status != 0 && vdcp->failfast_interval != 0) { /* * Operation has failed and failfast is enabled. * We need to check if the failure is due to a * reservation conflict if this was requested. */ check_resv_conflict = rconflict; } } } vdcp->sync_op_status = 0; vdcp->sync_op_blocked = B_FALSE; vdcp->sync_op_cnt--; /* signal the next waiting thread */ cv_signal(&vdcp->sync_blocked_cv); /* * We have to check for reservation conflict after unblocking sync * operations because some sync operations will be used to do this * check. */ if (check_resv_conflict) { vio = vdc_failfast_io_queue(vdcp, NULL); while (vio->vio_qtime != 0) cv_wait(&vdcp->failfast_io_cv, &vdcp->lock); kmem_free(vio, sizeof (vdc_io_t)); } mutex_exit(&vdcp->lock); return (status); } /* * Function: * vdc_drain_response() * * Description: * When a guest is panicking, the completion of requests needs to be * handled differently because interrupts are disabled and vdc * will not get messages. We have to poll for the messages instead. * * Arguments: * vdc - soft state pointer for this instance of the device driver. * * Return Code: * 0 - Success */ static int vdc_drain_response(vdc_t *vdc) { int rv, idx, retries; size_t msglen; vdc_local_desc_t *ldep = NULL; /* Local Dring Entry Pointer */ vio_dring_msg_t dmsg; mutex_enter(&vdc->lock); retries = 0; for (;;) { msglen = sizeof (dmsg); rv = ldc_read(vdc->ldc_handle, (caddr_t)&dmsg, &msglen); if (rv) { rv = EINVAL; break; } /* * if there are no packets wait and check again */ if ((rv == 0) && (msglen == 0)) { if (retries++ > vdc_dump_retries) { rv = EAGAIN; break; } drv_usecwait(vdc_usec_timeout_dump); continue; } /* * Ignore all messages that are not ACKs/NACKs to * DRing requests. */ if ((dmsg.tag.vio_msgtype != VIO_TYPE_DATA) || (dmsg.tag.vio_subtype_env != VIO_DRING_DATA)) { DMSG(vdc, 0, "discard pkt: type=%d sub=%d env=%d\n", dmsg.tag.vio_msgtype, dmsg.tag.vio_subtype, dmsg.tag.vio_subtype_env); continue; } /* * set the appropriate return value for the current request. */ switch (dmsg.tag.vio_subtype) { case VIO_SUBTYPE_ACK: rv = 0; break; case VIO_SUBTYPE_NACK: rv = EAGAIN; break; default: continue; } idx = dmsg.start_idx; if (idx >= vdc->dring_len) { DMSG(vdc, 0, "[%d] Bogus ack data : start %d\n", vdc->instance, idx); continue; } ldep = &vdc->local_dring[idx]; if (ldep->dep->hdr.dstate != VIO_DESC_DONE) { DMSG(vdc, 0, "[%d] Entry @ %d - state !DONE %d\n", vdc->instance, idx, ldep->dep->hdr.dstate); continue; } DMSG(vdc, 1, "[%d] Depopulating idx=%d state=%d\n", vdc->instance, idx, ldep->dep->hdr.dstate); rv = vdc_depopulate_descriptor(vdc, idx); if (rv) { DMSG(vdc, 0, "[%d] Entry @ %d - depopulate failed ..\n", vdc->instance, idx); } /* if this is the last descriptor - break out of loop */ if ((idx + 1) % vdc->dring_len == vdc->dring_curr_idx) break; } mutex_exit(&vdc->lock); DMSG(vdc, 0, "End idx=%d\n", idx); return (rv); } /* * Function: * vdc_depopulate_descriptor() * * Description: * * Arguments: * vdc - soft state pointer for this instance of the device driver. * idx - Index of the Descriptor Ring entry being modified * * Return Code: * 0 - Success */ static int vdc_depopulate_descriptor(vdc_t *vdc, uint_t idx) { vd_dring_entry_t *dep = NULL; /* Dring Entry Pointer */ vdc_local_desc_t *ldep = NULL; /* Local Dring Entry Pointer */ int status = ENXIO; int rv = 0; ASSERT(vdc != NULL); ASSERT(idx < vdc->dring_len); ldep = &vdc->local_dring[idx]; ASSERT(ldep != NULL); ASSERT(MUTEX_HELD(&vdc->lock)); DMSG(vdc, 2, ": idx = %d\n", idx); dep = ldep->dep; ASSERT(dep != NULL); ASSERT((dep->hdr.dstate == VIO_DESC_DONE) || (dep->payload.status == ECANCELED)); VDC_MARK_DRING_ENTRY_FREE(vdc, idx); ldep->is_free = B_TRUE; status = dep->payload.status; DMSG(vdc, 2, ": is_free = %d : status = %d\n", ldep->is_free, status); /* * If no buffers were used to transfer information to the server when * populating the descriptor then no memory handles need to be unbound * and we can return now. */ if (ldep->nbytes == 0) { cv_signal(&vdc->dring_free_cv); return (status); } /* * If the upper layer passed in a misaligned address we copied the * data into an aligned buffer before sending it to LDC - we now * copy it back to the original buffer. */ if (ldep->align_addr) { ASSERT(ldep->addr != NULL); if (dep->payload.nbytes > 0) bcopy(ldep->align_addr, ldep->addr, dep->payload.nbytes); kmem_free(ldep->align_addr, sizeof (caddr_t) * P2ROUNDUP(ldep->nbytes, 8)); ldep->align_addr = NULL; } rv = ldc_mem_unbind_handle(ldep->desc_mhdl); if (rv != 0) { DMSG(vdc, 0, "?[%d] unbind mhdl 0x%lx @ idx %d failed (%d)", vdc->instance, ldep->desc_mhdl, idx, rv); /* * The error returned by the vDisk server is more informative * and thus has a higher priority but if it isn't set we ensure * that this function returns an error. */ if (status == 0) status = EINVAL; } cv_signal(&vdc->membind_cv); cv_signal(&vdc->dring_free_cv); return (status); } /* * Function: * vdc_populate_mem_hdl() * * Description: * * Arguments: * vdc - soft state pointer for this instance of the device driver. * idx - Index of the Descriptor Ring entry being modified * addr - virtual address being mapped in * nybtes - number of bytes in 'addr' * operation - the vDisk operation being performed (VD_OP_xxx) * * Return Code: * 0 - Success */ static int vdc_populate_mem_hdl(vdc_t *vdcp, vdc_local_desc_t *ldep) { vd_dring_entry_t *dep = NULL; ldc_mem_handle_t mhdl; caddr_t vaddr; size_t nbytes; uint8_t perm = LDC_MEM_RW; uint8_t maptype; int rv = 0; int i; ASSERT(vdcp != NULL); dep = ldep->dep; mhdl = ldep->desc_mhdl; switch (ldep->dir) { case VIO_read_dir: perm = LDC_MEM_W; break; case VIO_write_dir: perm = LDC_MEM_R; break; case VIO_both_dir: perm = LDC_MEM_RW; break; default: ASSERT(0); /* catch bad programming in vdc */ } /* * LDC expects any addresses passed in to be 8-byte aligned. We need * to copy the contents of any misaligned buffers to a newly allocated * buffer and bind it instead (and copy the the contents back to the * original buffer passed in when depopulating the descriptor) */ vaddr = ldep->addr; nbytes = ldep->nbytes; if (((uint64_t)vaddr & 0x7) != 0) { ASSERT(ldep->align_addr == NULL); ldep->align_addr = kmem_alloc(sizeof (caddr_t) * P2ROUNDUP(nbytes, 8), KM_SLEEP); DMSG(vdcp, 0, "[%d] Misaligned address %p reallocating " "(buf=%p nb=%ld op=%d)\n", vdcp->instance, (void *)vaddr, (void *)ldep->align_addr, nbytes, ldep->operation); if (perm != LDC_MEM_W) bcopy(vaddr, ldep->align_addr, nbytes); vaddr = ldep->align_addr; } maptype = LDC_IO_MAP|LDC_SHADOW_MAP|LDC_DIRECT_MAP; rv = ldc_mem_bind_handle(mhdl, vaddr, P2ROUNDUP(nbytes, 8), maptype, perm, &dep->payload.cookie[0], &dep->payload.ncookies); DMSG(vdcp, 2, "[%d] bound mem handle; ncookies=%d\n", vdcp->instance, dep->payload.ncookies); if (rv != 0) { DMSG(vdcp, 0, "[%d] Failed to bind LDC memory handle " "(mhdl=%p, buf=%p, err=%d)\n", vdcp->instance, (void *)mhdl, (void *)vaddr, rv); if (ldep->align_addr) { kmem_free(ldep->align_addr, sizeof (caddr_t) * P2ROUNDUP(nbytes, 8)); ldep->align_addr = NULL; } return (EAGAIN); } /* * Get the other cookies (if any). */ for (i = 1; i < dep->payload.ncookies; i++) { rv = ldc_mem_nextcookie(mhdl, &dep->payload.cookie[i]); if (rv != 0) { (void) ldc_mem_unbind_handle(mhdl); DMSG(vdcp, 0, "?[%d] Failed to get next cookie " "(mhdl=%lx cnum=%d), err=%d", vdcp->instance, mhdl, i, rv); if (ldep->align_addr) { kmem_free(ldep->align_addr, sizeof (caddr_t) * ldep->nbytes); ldep->align_addr = NULL; } return (EAGAIN); } } return (rv); } /* * Interrupt handlers for messages from LDC */ /* * Function: * vdc_handle_cb() * * Description: * * Arguments: * event - Type of event (LDC_EVT_xxx) that triggered the callback * arg - soft state pointer for this instance of the device driver. * * Return Code: * 0 - Success */ static uint_t vdc_handle_cb(uint64_t event, caddr_t arg) { ldc_status_t ldc_state; int rv = 0; vdc_t *vdc = (vdc_t *)(void *)arg; ASSERT(vdc != NULL); DMSG(vdc, 1, "evt=%lx seqID=%ld\n", event, vdc->seq_num); /* * Depending on the type of event that triggered this callback, * we modify the handshake state or read the data. * * NOTE: not done as a switch() as event could be triggered by * a state change and a read request. Also the ordering of the * check for the event types is deliberate. */ if (event & LDC_EVT_UP) { DMSG(vdc, 0, "[%d] Received LDC_EVT_UP\n", vdc->instance); mutex_enter(&vdc->lock); /* get LDC state */ rv = ldc_status(vdc->ldc_handle, &ldc_state); if (rv != 0) { DMSG(vdc, 0, "[%d] Couldn't get LDC status %d", vdc->instance, rv); return (LDC_SUCCESS); } if (vdc->ldc_state != LDC_UP && ldc_state == LDC_UP) { /* * Reset the transaction sequence numbers when * LDC comes up. We then kick off the handshake * negotiation with the vDisk server. */ vdc->seq_num = 1; vdc->seq_num_reply = 0; vdc->ldc_state = ldc_state; cv_signal(&vdc->initwait_cv); } mutex_exit(&vdc->lock); } if (event & LDC_EVT_READ) { DMSG(vdc, 1, "[%d] Received LDC_EVT_READ\n", vdc->instance); mutex_enter(&vdc->read_lock); cv_signal(&vdc->read_cv); vdc->read_state = VDC_READ_PENDING; mutex_exit(&vdc->read_lock); /* that's all we have to do - no need to handle DOWN/RESET */ return (LDC_SUCCESS); } if (event & (LDC_EVT_RESET|LDC_EVT_DOWN)) { DMSG(vdc, 0, "[%d] Received LDC RESET event\n", vdc->instance); mutex_enter(&vdc->lock); /* * Need to wake up any readers so they will * detect that a reset has occurred. */ mutex_enter(&vdc->read_lock); if ((vdc->read_state == VDC_READ_WAITING) || (vdc->read_state == VDC_READ_RESET)) cv_signal(&vdc->read_cv); vdc->read_state = VDC_READ_RESET; mutex_exit(&vdc->read_lock); /* wake up any threads waiting for connection to come up */ if (vdc->state == VDC_STATE_INIT_WAITING) { vdc->state = VDC_STATE_RESETTING; cv_signal(&vdc->initwait_cv); } mutex_exit(&vdc->lock); } if (event & ~(LDC_EVT_UP | LDC_EVT_RESET | LDC_EVT_DOWN | LDC_EVT_READ)) DMSG(vdc, 0, "![%d] Unexpected LDC event (%lx) received", vdc->instance, event); return (LDC_SUCCESS); } /* * Function: * vdc_wait_for_response() * * Description: * Block waiting for a response from the server. If there is * no data the thread block on the read_cv that is signalled * by the callback when an EVT_READ occurs. * * Arguments: * vdcp - soft state pointer for this instance of the device driver. * * Return Code: * 0 - Success */ static int vdc_wait_for_response(vdc_t *vdcp, vio_msg_t *msgp) { size_t nbytes = sizeof (*msgp); int status; ASSERT(vdcp != NULL); DMSG(vdcp, 1, "[%d] Entered\n", vdcp->instance); status = vdc_recv(vdcp, msgp, &nbytes); DMSG(vdcp, 3, "vdc_read() done.. status=0x%x size=0x%x\n", status, (int)nbytes); if (status) { DMSG(vdcp, 0, "?[%d] Error %d reading LDC msg\n", vdcp->instance, status); return (status); } if (nbytes < sizeof (vio_msg_tag_t)) { DMSG(vdcp, 0, "?[%d] Expect %lu bytes; recv'd %lu\n", vdcp->instance, sizeof (vio_msg_tag_t), nbytes); return (ENOMSG); } DMSG(vdcp, 2, "[%d] (%x/%x/%x)\n", vdcp->instance, msgp->tag.vio_msgtype, msgp->tag.vio_subtype, msgp->tag.vio_subtype_env); /* * Verify the Session ID of the message * * Every message after the Version has been negotiated should * have the correct session ID set. */ if ((msgp->tag.vio_sid != vdcp->session_id) && (msgp->tag.vio_subtype_env != VIO_VER_INFO)) { DMSG(vdcp, 0, "[%d] Invalid SID: received 0x%x, " "expected 0x%lx [seq num %lx @ %d]", vdcp->instance, msgp->tag.vio_sid, vdcp->session_id, ((vio_dring_msg_t *)msgp)->seq_num, ((vio_dring_msg_t *)msgp)->start_idx); return (ENOMSG); } return (0); } /* * Function: * vdc_resubmit_backup_dring() * * Description: * Resubmit each descriptor in the backed up dring to * vDisk server. The Dring was backed up during connection * reset. * * Arguments: * vdcp - soft state pointer for this instance of the device driver. * * Return Code: * 0 - Success */ static int vdc_resubmit_backup_dring(vdc_t *vdcp) { int count; int b_idx; int rv; int dring_size; int status; vio_msg_t vio_msg; vdc_local_desc_t *curr_ldep; ASSERT(MUTEX_NOT_HELD(&vdcp->lock)); ASSERT(vdcp->state == VDC_STATE_HANDLE_PENDING); if (vdcp->local_dring_backup == NULL) { /* the pending requests have already been processed */ return (0); } DMSG(vdcp, 1, "restoring pending dring entries (len=%d, tail=%d)\n", vdcp->local_dring_backup_len, vdcp->local_dring_backup_tail); /* * Walk the backup copy of the local descriptor ring and * resubmit all the outstanding transactions. */ b_idx = vdcp->local_dring_backup_tail; for (count = 0; count < vdcp->local_dring_backup_len; count++) { curr_ldep = &(vdcp->local_dring_backup[b_idx]); /* only resubmit outstanding transactions */ if (!curr_ldep->is_free) { DMSG(vdcp, 1, "resubmitting entry idx=%x\n", b_idx); mutex_enter(&vdcp->lock); rv = vdc_populate_descriptor(vdcp, curr_ldep->operation, curr_ldep->addr, curr_ldep->nbytes, curr_ldep->slice, curr_ldep->offset, curr_ldep->cb_type, curr_ldep->cb_arg, curr_ldep->dir); mutex_exit(&vdcp->lock); if (rv) { DMSG(vdcp, 1, "[%d] cannot resubmit entry %d\n", vdcp->instance, b_idx); return (rv); } /* Wait for the response message. */ DMSG(vdcp, 1, "waiting for response to idx=%x\n", b_idx); status = vdc_wait_for_response(vdcp, &vio_msg); if (status) { DMSG(vdcp, 1, "[%d] wait_for_response " "returned err=%d\n", vdcp->instance, status); return (status); } DMSG(vdcp, 1, "processing msg for idx=%x\n", b_idx); status = vdc_process_data_msg(vdcp, &vio_msg); if (status) { DMSG(vdcp, 1, "[%d] process_data_msg " "returned err=%d\n", vdcp->instance, status); return (status); } } /* get the next element to submit */ if (++b_idx >= vdcp->local_dring_backup_len) b_idx = 0; } /* all done - now clear up pending dring copy */ dring_size = vdcp->local_dring_backup_len * sizeof (vdcp->local_dring_backup[0]); (void) kmem_free(vdcp->local_dring_backup, dring_size); vdcp->local_dring_backup = NULL; return (0); } /* * Function: * vdc_cancel_backup_dring * * Description: * Cancel each descriptor in the backed up dring to vDisk server. * The Dring was backed up during connection reset. * * Arguments: * vdcp - soft state pointer for this instance of the device driver. * * Return Code: * None */ void vdc_cancel_backup_ring(vdc_t *vdcp) { vdc_local_desc_t *ldep; struct buf *bufp; int count; int b_idx; int dring_size; ASSERT(MUTEX_HELD(&vdcp->lock)); ASSERT(vdcp->state == VDC_STATE_INIT || vdcp->state == VDC_STATE_INIT_WAITING || vdcp->state == VDC_STATE_NEGOTIATE || vdcp->state == VDC_STATE_RESETTING); if (vdcp->local_dring_backup == NULL) { /* the pending requests have already been processed */ return; } DMSG(vdcp, 1, "cancelling pending dring entries (len=%d, tail=%d)\n", vdcp->local_dring_backup_len, vdcp->local_dring_backup_tail); /* * Walk the backup copy of the local descriptor ring and * cancel all the outstanding transactions. */ b_idx = vdcp->local_dring_backup_tail; for (count = 0; count < vdcp->local_dring_backup_len; count++) { ldep = &(vdcp->local_dring_backup[b_idx]); /* only cancel outstanding transactions */ if (!ldep->is_free) { DMSG(vdcp, 1, "cancelling entry idx=%x\n", b_idx); /* * All requests have already been cleared from the * local descriptor ring and the LDC channel has been * reset so we will never get any reply for these * requests. Now we just have to notify threads waiting * for replies that the request has failed. */ switch (ldep->cb_type) { case CB_SYNC: ASSERT(vdcp->sync_op_pending); vdcp->sync_op_status = EIO; vdcp->sync_op_pending = B_FALSE; cv_signal(&vdcp->sync_pending_cv); break; case CB_STRATEGY: bufp = ldep->cb_arg; ASSERT(bufp != NULL); bufp->b_resid = bufp->b_bcount; bioerror(bufp, EIO); biodone(bufp); break; default: ASSERT(0); } } /* get the next element to cancel */ if (++b_idx >= vdcp->local_dring_backup_len) b_idx = 0; } /* all done - now clear up pending dring copy */ dring_size = vdcp->local_dring_backup_len * sizeof (vdcp->local_dring_backup[0]); (void) kmem_free(vdcp->local_dring_backup, dring_size); vdcp->local_dring_backup = NULL; DTRACE_IO2(processed, int, count, vdc_t *, vdcp); } /* * Function: * vdc_connection_timeout * * Description: * This function is invoked if the timeout set to establish the connection * with vds expires. This will happen if we spend too much time in the * VDC_STATE_INIT_WAITING or VDC_STATE_NEGOTIATE states. Then we will * cancel any pending request and mark them as failed. * * If the timeout does not expire, it will be cancelled when we reach the * VDC_STATE_HANDLE_PENDING or VDC_STATE_RESETTING state. This function can * be invoked while we are in the VDC_STATE_HANDLE_PENDING or * VDC_STATE_RESETTING state in which case we do nothing because the * timeout is being cancelled. * * Arguments: * arg - argument of the timeout function actually a soft state * pointer for the instance of the device driver. * * Return Code: * None */ void vdc_connection_timeout(void *arg) { vdc_t *vdcp = (vdc_t *)arg; mutex_enter(&vdcp->lock); if (vdcp->state == VDC_STATE_HANDLE_PENDING || vdcp->state == VDC_STATE_DETACH) { /* * The connection has just been re-established or * we are detaching. */ vdcp->ctimeout_reached = B_FALSE; mutex_exit(&vdcp->lock); return; } vdcp->ctimeout_reached = B_TRUE; /* notify requests waiting for sending */ cv_broadcast(&vdcp->running_cv); /* cancel requests waiting for a result */ vdc_cancel_backup_ring(vdcp); mutex_exit(&vdcp->lock); cmn_err(CE_NOTE, "[%d] connection to service domain timeout", vdcp->instance); } /* * Function: * vdc_backup_local_dring() * * Description: * Backup the current dring in the event of a reset. The Dring * transactions will be resubmitted to the server when the * connection is restored. * * Arguments: * vdcp - soft state pointer for this instance of the device driver. * * Return Code: * NONE */ static void vdc_backup_local_dring(vdc_t *vdcp) { int dring_size; ASSERT(MUTEX_HELD(&vdcp->lock)); ASSERT(vdcp->state == VDC_STATE_RESETTING); /* * If the backup dring is stil around, it means * that the last restore did not complete. However, * since we never got back into the running state, * the backup copy we have is still valid. */ if (vdcp->local_dring_backup != NULL) { DMSG(vdcp, 1, "reusing local descriptor ring backup " "(len=%d, tail=%d)\n", vdcp->local_dring_backup_len, vdcp->local_dring_backup_tail); return; } /* * The backup dring can be NULL and the local dring may not be * initialized. This can happen if we had a reset while establishing * a new connection but after the connection has timed out. In that * case the backup dring is NULL because the requests have been * cancelled and the request occured before the local dring is * initialized. */ if (!(vdcp->initialized & VDC_DRING_LOCAL)) return; DMSG(vdcp, 1, "backing up the local descriptor ring (len=%d, " "tail=%d)\n", vdcp->dring_len, vdcp->dring_curr_idx); dring_size = vdcp->dring_len * sizeof (vdcp->local_dring[0]); vdcp->local_dring_backup = kmem_alloc(dring_size, KM_SLEEP); bcopy(vdcp->local_dring, vdcp->local_dring_backup, dring_size); vdcp->local_dring_backup_tail = vdcp->dring_curr_idx; vdcp->local_dring_backup_len = vdcp->dring_len; } /* -------------------------------------------------------------------------- */ /* * The following functions process the incoming messages from vds */ /* * Function: * vdc_process_msg_thread() * * Description: * * Main VDC message processing thread. Each vDisk instance * consists of a copy of this thread. This thread triggers * all the handshakes and data exchange with the server. It * also handles all channel resets * * Arguments: * vdc - soft state pointer for this instance of the device driver. * * Return Code: * None */ static void vdc_process_msg_thread(vdc_t *vdcp) { int status; int ctimeout; timeout_id_t tmid = 0; mutex_enter(&vdcp->lock); for (;;) { #define Q(_s) (vdcp->state == _s) ? #_s : DMSG(vdcp, 3, "state = %d (%s)\n", vdcp->state, Q(VDC_STATE_INIT) Q(VDC_STATE_INIT_WAITING) Q(VDC_STATE_NEGOTIATE) Q(VDC_STATE_HANDLE_PENDING) Q(VDC_STATE_RUNNING) Q(VDC_STATE_RESETTING) Q(VDC_STATE_DETACH) "UNKNOWN"); switch (vdcp->state) { case VDC_STATE_INIT: /* * If requested, start a timeout to check if the * connection with vds is established in the * specified delay. If the timeout expires, we * will cancel any pending request. * * If some reset have occurred while establishing * the connection, we already have a timeout armed * and in that case we don't need to arm a new one. */ ctimeout = (vdc_timeout != 0)? vdc_timeout : vdcp->ctimeout; if (ctimeout != 0 && tmid == 0) { tmid = timeout(vdc_connection_timeout, vdcp, ctimeout * drv_usectohz(1000000)); } /* Check if have re-initializing repeatedly */ if (vdcp->hshake_cnt++ > vdc_hshake_retries && vdcp->lifecycle != VDC_LC_ONLINE) { cmn_err(CE_NOTE, "[%d] disk access failed.\n", vdcp->instance); vdcp->state = VDC_STATE_DETACH; break; } /* Bring up connection with vds via LDC */ status = vdc_start_ldc_connection(vdcp); if (status == EINVAL) { DMSG(vdcp, 0, "[%d] Could not start LDC", vdcp->instance); vdcp->state = VDC_STATE_DETACH; } else { vdcp->state = VDC_STATE_INIT_WAITING; } break; case VDC_STATE_INIT_WAITING: /* * Let the callback event move us on * when channel is open to server */ while (vdcp->ldc_state != LDC_UP) { cv_wait(&vdcp->initwait_cv, &vdcp->lock); if (vdcp->state != VDC_STATE_INIT_WAITING) { DMSG(vdcp, 0, "state moved to %d out from under us...\n", vdcp->state); break; } } if (vdcp->state == VDC_STATE_INIT_WAITING && vdcp->ldc_state == LDC_UP) { vdcp->state = VDC_STATE_NEGOTIATE; } break; case VDC_STATE_NEGOTIATE: switch (status = vdc_ver_negotiation(vdcp)) { case 0: break; default: DMSG(vdcp, 0, "ver negotiate failed (%d)..\n", status); goto reset; } switch (status = vdc_attr_negotiation(vdcp)) { case 0: break; default: DMSG(vdcp, 0, "attr negotiate failed (%d)..\n", status); goto reset; } switch (status = vdc_dring_negotiation(vdcp)) { case 0: break; default: DMSG(vdcp, 0, "dring negotiate failed (%d)..\n", status); goto reset; } switch (status = vdc_rdx_exchange(vdcp)) { case 0: vdcp->state = VDC_STATE_HANDLE_PENDING; goto done; default: DMSG(vdcp, 0, "RDX xchg failed ..(%d)\n", status); goto reset; } reset: DMSG(vdcp, 0, "negotiation failed: resetting (%d)\n", status); vdcp->state = VDC_STATE_RESETTING; vdcp->self_reset = B_TRUE; done: DMSG(vdcp, 0, "negotiation complete (state=0x%x)...\n", vdcp->state); break; case VDC_STATE_HANDLE_PENDING: if (vdcp->ctimeout_reached) { /* * The connection timeout had been reached so * pending requests have been cancelled. Now * that the connection is back we can reset * the timeout. */ ASSERT(vdcp->local_dring_backup == NULL); ASSERT(tmid != 0); tmid = 0; vdcp->ctimeout_reached = B_FALSE; vdcp->state = VDC_STATE_RUNNING; DMSG(vdcp, 0, "[%d] connection to service " "domain is up", vdcp->instance); break; } mutex_exit(&vdcp->lock); if (tmid != 0) { (void) untimeout(tmid); tmid = 0; } status = vdc_resubmit_backup_dring(vdcp); mutex_enter(&vdcp->lock); if (status) vdcp->state = VDC_STATE_RESETTING; else vdcp->state = VDC_STATE_RUNNING; break; /* enter running state */ case VDC_STATE_RUNNING: /* * Signal anyone waiting for the connection * to come on line. */ vdcp->hshake_cnt = 0; cv_broadcast(&vdcp->running_cv); /* failfast has to been checked after reset */ cv_signal(&vdcp->failfast_cv); /* ownership is lost during reset */ if (vdcp->ownership & VDC_OWNERSHIP_WANTED) vdcp->ownership |= VDC_OWNERSHIP_RESET; cv_signal(&vdcp->ownership_cv); mutex_exit(&vdcp->lock); for (;;) { vio_msg_t msg; status = vdc_wait_for_response(vdcp, &msg); if (status) break; DMSG(vdcp, 1, "[%d] new pkt(s) available\n", vdcp->instance); status = vdc_process_data_msg(vdcp, &msg); if (status) { DMSG(vdcp, 1, "[%d] process_data_msg " "returned err=%d\n", vdcp->instance, status); break; } } mutex_enter(&vdcp->lock); vdcp->state = VDC_STATE_RESETTING; vdcp->self_reset = B_TRUE; break; case VDC_STATE_RESETTING: /* * When we reach this state, we either come from the * VDC_STATE_RUNNING state and we can have pending * request but no timeout is armed; or we come from * the VDC_STATE_INIT_WAITING, VDC_NEGOTIATE or * VDC_HANDLE_PENDING state and there is no pending * request or pending requests have already been copied * into the backup dring. So we can safely keep the * connection timeout armed while we are in this state. */ DMSG(vdcp, 0, "Initiating channel reset " "(pending = %d)\n", (int)vdcp->threads_pending); if (vdcp->self_reset) { DMSG(vdcp, 0, "[%d] calling stop_ldc_connection.\n", vdcp->instance); status = vdc_stop_ldc_connection(vdcp); vdcp->self_reset = B_FALSE; } /* * Wait for all threads currently waiting * for a free dring entry to use. */ while (vdcp->threads_pending) { cv_broadcast(&vdcp->membind_cv); cv_broadcast(&vdcp->dring_free_cv); mutex_exit(&vdcp->lock); /* give the waiters enough time to wake up */ delay(vdc_hz_min_ldc_delay); mutex_enter(&vdcp->lock); } ASSERT(vdcp->threads_pending == 0); /* Sanity check that no thread is receiving */ ASSERT(vdcp->read_state != VDC_READ_WAITING); vdcp->read_state = VDC_READ_IDLE; vdc_backup_local_dring(vdcp); /* cleanup the old d-ring */ vdc_destroy_descriptor_ring(vdcp); /* go and start again */ vdcp->state = VDC_STATE_INIT; break; case VDC_STATE_DETACH: DMSG(vdcp, 0, "[%d] Reset thread exit cleanup ..\n", vdcp->instance); /* cancel any pending timeout */ mutex_exit(&vdcp->lock); if (tmid != 0) { (void) untimeout(tmid); tmid = 0; } mutex_enter(&vdcp->lock); /* * Signal anyone waiting for connection * to come online */ cv_broadcast(&vdcp->running_cv); while (vdcp->sync_op_pending) { cv_signal(&vdcp->sync_pending_cv); cv_signal(&vdcp->sync_blocked_cv); mutex_exit(&vdcp->lock); /* give the waiters enough time to wake up */ delay(vdc_hz_min_ldc_delay); mutex_enter(&vdcp->lock); } mutex_exit(&vdcp->lock); DMSG(vdcp, 0, "[%d] Msg processing thread exiting ..\n", vdcp->instance); thread_exit(); break; } } } /* * Function: * vdc_process_data_msg() * * Description: * This function is called by the message processing thread each time * a message with a msgtype of VIO_TYPE_DATA is received. It will either * be an ACK or NACK from vds[1] which vdc handles as follows. * ACK - wake up the waiting thread * NACK - resend any messages necessary * * [1] Although the message format allows it, vds should not send a * VIO_SUBTYPE_INFO message to vdc asking it to read data; if for * some bizarre reason it does, vdc will reset the connection. * * Arguments: * vdc - soft state pointer for this instance of the device driver. * msg - the LDC message sent by vds * * Return Code: * 0 - Success. * > 0 - error value returned by LDC */ static int vdc_process_data_msg(vdc_t *vdcp, vio_msg_t *msg) { int status = 0; vio_dring_msg_t *dring_msg; vdc_local_desc_t *ldep = NULL; int start, end; int idx; dring_msg = (vio_dring_msg_t *)msg; ASSERT(msg->tag.vio_msgtype == VIO_TYPE_DATA); ASSERT(vdcp != NULL); mutex_enter(&vdcp->lock); /* * Check to see if the message has bogus data */ idx = start = dring_msg->start_idx; end = dring_msg->end_idx; if ((start >= vdcp->dring_len) || (end >= vdcp->dring_len) || (end < -1)) { DMSG(vdcp, 0, "[%d] Bogus ACK data : start %d, end %d\n", vdcp->instance, start, end); mutex_exit(&vdcp->lock); return (EINVAL); } /* * Verify that the sequence number is what vdc expects. */ switch (vdc_verify_seq_num(vdcp, dring_msg)) { case VDC_SEQ_NUM_TODO: break; /* keep processing this message */ case VDC_SEQ_NUM_SKIP: mutex_exit(&vdcp->lock); return (0); case VDC_SEQ_NUM_INVALID: mutex_exit(&vdcp->lock); DMSG(vdcp, 0, "[%d] invalid seqno\n", vdcp->instance); return (ENXIO); } if (msg->tag.vio_subtype == VIO_SUBTYPE_NACK) { DMSG(vdcp, 0, "[%d] DATA NACK\n", vdcp->instance); VDC_DUMP_DRING_MSG(dring_msg); mutex_exit(&vdcp->lock); return (EIO); } else if (msg->tag.vio_subtype == VIO_SUBTYPE_INFO) { mutex_exit(&vdcp->lock); return (EPROTO); } DTRACE_IO2(recv, vio_dring_msg_t, dring_msg, vdc_t *, vdcp); DMSG(vdcp, 1, ": start %d end %d\n", start, end); ASSERT(start == end); ldep = &vdcp->local_dring[idx]; DMSG(vdcp, 1, ": state 0x%x - cb_type 0x%x\n", ldep->dep->hdr.dstate, ldep->cb_type); if (ldep->dep->hdr.dstate == VIO_DESC_DONE) { struct buf *bufp; switch (ldep->cb_type) { case CB_SYNC: ASSERT(vdcp->sync_op_pending); status = vdc_depopulate_descriptor(vdcp, idx); vdcp->sync_op_status = status; vdcp->sync_op_pending = B_FALSE; cv_signal(&vdcp->sync_pending_cv); break; case CB_STRATEGY: bufp = ldep->cb_arg; ASSERT(bufp != NULL); bufp->b_resid = bufp->b_bcount - ldep->dep->payload.nbytes; status = ldep->dep->payload.status; /* Future:ntoh */ if (status != 0) { DMSG(vdcp, 1, "strategy status=%d\n", status); bioerror(bufp, status); } (void) vdc_depopulate_descriptor(vdcp, idx); DMSG(vdcp, 1, "strategy complete req=%ld bytes resp=%ld bytes\n", bufp->b_bcount, ldep->dep->payload.nbytes); if (status != 0 && vdcp->failfast_interval != 0) { /* * The I/O has failed and failfast is enabled. * We need the failfast thread to check if the * failure is due to a reservation conflict. */ (void) vdc_failfast_io_queue(vdcp, bufp); } else { biodone(bufp); } break; default: ASSERT(0); } } /* let the arrival signal propogate */ mutex_exit(&vdcp->lock); /* probe gives the count of how many entries were processed */ DTRACE_IO2(processed, int, 1, vdc_t *, vdcp); return (0); } /* * Function: * vdc_handle_ver_msg() * * Description: * * Arguments: * vdc - soft state pointer for this instance of the device driver. * ver_msg - LDC message sent by vDisk server * * Return Code: * 0 - Success */ static int vdc_handle_ver_msg(vdc_t *vdc, vio_ver_msg_t *ver_msg) { int status = 0; ASSERT(vdc != NULL); ASSERT(mutex_owned(&vdc->lock)); if (ver_msg->tag.vio_subtype_env != VIO_VER_INFO) { return (EPROTO); } if (ver_msg->dev_class != VDEV_DISK_SERVER) { return (EINVAL); } switch (ver_msg->tag.vio_subtype) { case VIO_SUBTYPE_ACK: /* * We check to see if the version returned is indeed supported * (The server may have also adjusted the minor number downwards * and if so 'ver_msg' will contain the actual version agreed) */ if (vdc_is_supported_version(ver_msg)) { vdc->ver.major = ver_msg->ver_major; vdc->ver.minor = ver_msg->ver_minor; ASSERT(vdc->ver.major > 0); } else { status = EPROTO; } break; case VIO_SUBTYPE_NACK: /* * call vdc_is_supported_version() which will return the next * supported version (if any) in 'ver_msg' */ (void) vdc_is_supported_version(ver_msg); if (ver_msg->ver_major > 0) { size_t len = sizeof (*ver_msg); ASSERT(vdc->ver.major > 0); /* reset the necessary fields and resend */ ver_msg->tag.vio_subtype = VIO_SUBTYPE_INFO; ver_msg->dev_class = VDEV_DISK; status = vdc_send(vdc, (caddr_t)ver_msg, &len); DMSG(vdc, 0, "[%d] Resend VER info (LDC status = %d)\n", vdc->instance, status); if (len != sizeof (*ver_msg)) status = EBADMSG; } else { DMSG(vdc, 0, "[%d] No common version with vDisk server", vdc->instance); status = ENOTSUP; } break; case VIO_SUBTYPE_INFO: /* * Handle the case where vds starts handshake * (for now only vdc is the instigator) */ status = ENOTSUP; break; default: status = EINVAL; break; } return (status); } /* * Function: * vdc_handle_attr_msg() * * Description: * * Arguments: * vdc - soft state pointer for this instance of the device driver. * attr_msg - LDC message sent by vDisk server * * Return Code: * 0 - Success */ static int vdc_handle_attr_msg(vdc_t *vdc, vd_attr_msg_t *attr_msg) { int status = 0; ASSERT(vdc != NULL); ASSERT(mutex_owned(&vdc->lock)); if (attr_msg->tag.vio_subtype_env != VIO_ATTR_INFO) { return (EPROTO); } switch (attr_msg->tag.vio_subtype) { case VIO_SUBTYPE_ACK: /* * We now verify the attributes sent by vds. */ if (attr_msg->vdisk_size == 0) { DMSG(vdc, 0, "[%d] Invalid disk size from vds", vdc->instance); status = EINVAL; break; } if (attr_msg->max_xfer_sz == 0) { DMSG(vdc, 0, "[%d] Invalid transfer size from vds", vdc->instance); status = EINVAL; break; } if (attr_msg->vdisk_size == VD_SIZE_UNKNOWN) { DMSG(vdc, 0, "[%d] Unknown disk size from vds", vdc->instance); attr_msg->vdisk_size = 0; } /* * If the disk size is already set check that it hasn't changed. */ if ((vdc->vdisk_size != 0) && (attr_msg->vdisk_size != 0) && (vdc->vdisk_size != attr_msg->vdisk_size)) { DMSG(vdc, 0, "[%d] Different disk size from vds " "(old=0x%lx - new=0x%lx", vdc->instance, vdc->vdisk_size, attr_msg->vdisk_size) status = EINVAL; break; } vdc->vdisk_size = attr_msg->vdisk_size; vdc->vdisk_type = attr_msg->vdisk_type; vdc->operations = attr_msg->operations; if (vio_ver_is_supported(vdc->ver, 1, 1)) vdc->vdisk_media = attr_msg->vdisk_media; else vdc->vdisk_media = 0; DMSG(vdc, 0, "[%d] max_xfer_sz: sent %lx acked %lx\n", vdc->instance, vdc->max_xfer_sz, attr_msg->max_xfer_sz); DMSG(vdc, 0, "[%d] vdisk_block_size: sent %lx acked %x\n", vdc->instance, vdc->block_size, attr_msg->vdisk_block_size); /* * We don't know at compile time what the vDisk server will * think are good values but we apply a large (arbitrary) * upper bound to prevent memory exhaustion in vdc if it was * allocating a DRing based of huge values sent by the server. * We probably will never exceed this except if the message * was garbage. */ if ((attr_msg->max_xfer_sz * attr_msg->vdisk_block_size) <= (PAGESIZE * DEV_BSIZE)) { vdc->max_xfer_sz = attr_msg->max_xfer_sz; vdc->block_size = attr_msg->vdisk_block_size; } else { DMSG(vdc, 0, "[%d] vds block transfer size too big;" " using max supported by vdc", vdc->instance); } if ((attr_msg->xfer_mode != VIO_DRING_MODE) || (attr_msg->vdisk_size > INT64_MAX) || (attr_msg->operations == 0) || (attr_msg->vdisk_type > VD_DISK_TYPE_DISK)) { DMSG(vdc, 0, "[%d] Invalid attributes from vds", vdc->instance); status = EINVAL; break; } /* * Now that we have received all attributes we can create a * fake geometry for the disk. */ vdc_create_fake_geometry(vdc); break; case VIO_SUBTYPE_NACK: /* * vds could not handle the attributes we sent so we * stop negotiating. */ status = EPROTO; break; case VIO_SUBTYPE_INFO: /* * Handle the case where vds starts the handshake * (for now; vdc is the only supported instigatior) */ status = ENOTSUP; break; default: status = ENOTSUP; break; } return (status); } /* * Function: * vdc_handle_dring_reg_msg() * * Description: * * Arguments: * vdc - soft state pointer for this instance of the driver. * dring_msg - LDC message sent by vDisk server * * Return Code: * 0 - Success */ static int vdc_handle_dring_reg_msg(vdc_t *vdc, vio_dring_reg_msg_t *dring_msg) { int status = 0; ASSERT(vdc != NULL); ASSERT(mutex_owned(&vdc->lock)); if (dring_msg->tag.vio_subtype_env != VIO_DRING_REG) { return (EPROTO); } switch (dring_msg->tag.vio_subtype) { case VIO_SUBTYPE_ACK: /* save the received dring_ident */ vdc->dring_ident = dring_msg->dring_ident; DMSG(vdc, 0, "[%d] Received dring ident=0x%lx\n", vdc->instance, vdc->dring_ident); break; case VIO_SUBTYPE_NACK: /* * vds could not handle the DRing info we sent so we * stop negotiating. */ DMSG(vdc, 0, "[%d] server could not register DRing\n", vdc->instance); status = EPROTO; break; case VIO_SUBTYPE_INFO: /* * Handle the case where vds starts handshake * (for now only vdc is the instigatior) */ status = ENOTSUP; break; default: status = ENOTSUP; } return (status); } /* * Function: * vdc_verify_seq_num() * * Description: * This functions verifies that the sequence number sent back by the vDisk * server with the latest message is what is expected (i.e. it is greater * than the last seq num sent by the vDisk server and less than or equal * to the last seq num generated by vdc). * * It then checks the request ID to see if any requests need processing * in the DRing. * * Arguments: * vdc - soft state pointer for this instance of the driver. * dring_msg - pointer to the LDC message sent by vds * * Return Code: * VDC_SEQ_NUM_TODO - Message needs to be processed * VDC_SEQ_NUM_SKIP - Message has already been processed * VDC_SEQ_NUM_INVALID - The seq numbers are so out of sync, * vdc cannot deal with them */ static int vdc_verify_seq_num(vdc_t *vdc, vio_dring_msg_t *dring_msg) { ASSERT(vdc != NULL); ASSERT(dring_msg != NULL); ASSERT(mutex_owned(&vdc->lock)); /* * Check to see if the messages were responded to in the correct * order by vds. */ if ((dring_msg->seq_num <= vdc->seq_num_reply) || (dring_msg->seq_num > vdc->seq_num)) { DMSG(vdc, 0, "?[%d] Bogus sequence_number %lu: " "%lu > expected <= %lu (last proc req %lu sent %lu)\n", vdc->instance, dring_msg->seq_num, vdc->seq_num_reply, vdc->seq_num, vdc->req_id_proc, vdc->req_id); return (VDC_SEQ_NUM_INVALID); } vdc->seq_num_reply = dring_msg->seq_num; if (vdc->req_id_proc < vdc->req_id) return (VDC_SEQ_NUM_TODO); else return (VDC_SEQ_NUM_SKIP); } /* * Function: * vdc_is_supported_version() * * Description: * This routine checks if the major/minor version numbers specified in * 'ver_msg' are supported. If not it finds the next version that is * in the supported version list 'vdc_version[]' and sets the fields in * 'ver_msg' to those values * * Arguments: * ver_msg - LDC message sent by vDisk server * * Return Code: * B_TRUE - Success * B_FALSE - Version not supported */ static boolean_t vdc_is_supported_version(vio_ver_msg_t *ver_msg) { int vdc_num_versions = sizeof (vdc_version) / sizeof (vdc_version[0]); for (int i = 0; i < vdc_num_versions; i++) { ASSERT(vdc_version[i].major > 0); ASSERT((i == 0) || (vdc_version[i].major < vdc_version[i-1].major)); /* * If the major versions match, adjust the minor version, if * necessary, down to the highest value supported by this * client. The server should support all minor versions lower * than the value it sent */ if (ver_msg->ver_major == vdc_version[i].major) { if (ver_msg->ver_minor > vdc_version[i].minor) { DMSGX(0, "Adjusting minor version from %u to %u", ver_msg->ver_minor, vdc_version[i].minor); ver_msg->ver_minor = vdc_version[i].minor; } return (B_TRUE); } /* * If the message contains a higher major version number, set * the message's major/minor versions to the current values * and return false, so this message will get resent with * these values, and the server will potentially try again * with the same or a lower version */ if (ver_msg->ver_major > vdc_version[i].major) { ver_msg->ver_major = vdc_version[i].major; ver_msg->ver_minor = vdc_version[i].minor; DMSGX(0, "Suggesting major/minor (0x%x/0x%x)\n", ver_msg->ver_major, ver_msg->ver_minor); return (B_FALSE); } /* * Otherwise, the message's major version is less than the * current major version, so continue the loop to the next * (lower) supported version */ } /* * No common version was found; "ground" the version pair in the * message to terminate negotiation */ ver_msg->ver_major = 0; ver_msg->ver_minor = 0; return (B_FALSE); } /* -------------------------------------------------------------------------- */ /* * DKIO(7) support */ typedef struct vdc_dk_arg { struct dk_callback dkc; int mode; dev_t dev; vdc_t *vdc; } vdc_dk_arg_t; /* * Function: * vdc_dkio_flush_cb() * * Description: * This routine is a callback for DKIOCFLUSHWRITECACHE which can be called * by kernel code. * * Arguments: * arg - a pointer to a vdc_dk_arg_t structure. */ void vdc_dkio_flush_cb(void *arg) { struct vdc_dk_arg *dk_arg = (struct vdc_dk_arg *)arg; struct dk_callback *dkc = NULL; vdc_t *vdc = NULL; int rv; if (dk_arg == NULL) { cmn_err(CE_NOTE, "?[Unk] DKIOCFLUSHWRITECACHE arg is NULL\n"); return; } dkc = &dk_arg->dkc; vdc = dk_arg->vdc; ASSERT(vdc != NULL); rv = vdc_do_sync_op(vdc, VD_OP_FLUSH, NULL, 0, VDCPART(dk_arg->dev), 0, CB_SYNC, 0, VIO_both_dir, B_TRUE); if (rv != 0) { DMSG(vdc, 0, "[%d] DKIOCFLUSHWRITECACHE failed %d : model %x\n", vdc->instance, rv, ddi_model_convert_from(dk_arg->mode & FMODELS)); } /* * Trigger the call back to notify the caller the the ioctl call has * been completed. */ if ((dk_arg->mode & FKIOCTL) && (dkc != NULL) && (dkc->dkc_callback != NULL)) { ASSERT(dkc->dkc_cookie != NULL); (*dkc->dkc_callback)(dkc->dkc_cookie, rv); } /* Indicate that one less DKIO write flush is outstanding */ mutex_enter(&vdc->lock); vdc->dkio_flush_pending--; ASSERT(vdc->dkio_flush_pending >= 0); mutex_exit(&vdc->lock); /* free the mem that was allocated when the callback was dispatched */ kmem_free(arg, sizeof (vdc_dk_arg_t)); } /* * Function: * vdc_dkio_get_partition() * * Description: * This function implements the DKIOCGAPART ioctl. * * Arguments: * vdc - soft state pointer * arg - a pointer to a dk_map[NDKMAP] or dk_map32[NDKMAP] structure * flag - ioctl flags */ static int vdc_dkio_get_partition(vdc_t *vdc, caddr_t arg, int flag) { struct dk_geom *geom; struct vtoc *vtoc; union { struct dk_map map[NDKMAP]; struct dk_map32 map32[NDKMAP]; } data; int i, rv, size; mutex_enter(&vdc->lock); if ((rv = vdc_validate_geometry(vdc)) != 0) { mutex_exit(&vdc->lock); return (rv); } vtoc = vdc->vtoc; geom = vdc->geom; if (ddi_model_convert_from(flag & FMODELS) == DDI_MODEL_ILP32) { for (i = 0; i < vtoc->v_nparts; i++) { data.map32[i].dkl_cylno = vtoc->v_part[i].p_start / (geom->dkg_nhead * geom->dkg_nsect); data.map32[i].dkl_nblk = vtoc->v_part[i].p_size; } size = NDKMAP * sizeof (struct dk_map32); } else { for (i = 0; i < vtoc->v_nparts; i++) { data.map[i].dkl_cylno = vtoc->v_part[i].p_start / (geom->dkg_nhead * geom->dkg_nsect); data.map[i].dkl_nblk = vtoc->v_part[i].p_size; } size = NDKMAP * sizeof (struct dk_map); } mutex_exit(&vdc->lock); if (ddi_copyout(&data, arg, size, flag) != 0) return (EFAULT); return (0); } /* * Function: * vdc_dioctl_rwcmd() * * Description: * This function implements the DIOCTL_RWCMD ioctl. This ioctl is used * for DKC_DIRECT disks to read or write at an absolute disk offset. * * Arguments: * dev - device * arg - a pointer to a dadkio_rwcmd or dadkio_rwcmd32 structure * flag - ioctl flags */ static int vdc_dioctl_rwcmd(dev_t dev, caddr_t arg, int flag) { struct dadkio_rwcmd32 rwcmd32; struct dadkio_rwcmd rwcmd; struct iovec aiov; struct uio auio; int rw, status; struct buf *buf; if (ddi_model_convert_from(flag & FMODELS) == DDI_MODEL_ILP32) { if (ddi_copyin((caddr_t)arg, (caddr_t)&rwcmd32, sizeof (struct dadkio_rwcmd32), flag)) { return (EFAULT); } rwcmd.cmd = rwcmd32.cmd; rwcmd.flags = rwcmd32.flags; rwcmd.blkaddr = (daddr_t)rwcmd32.blkaddr; rwcmd.buflen = rwcmd32.buflen; rwcmd.bufaddr = (caddr_t)(uintptr_t)rwcmd32.bufaddr; } else { if (ddi_copyin((caddr_t)arg, (caddr_t)&rwcmd, sizeof (struct dadkio_rwcmd), flag)) { return (EFAULT); } } switch (rwcmd.cmd) { case DADKIO_RWCMD_READ: rw = B_READ; break; case DADKIO_RWCMD_WRITE: rw = B_WRITE; break; default: return (EINVAL); } bzero((caddr_t)&aiov, sizeof (struct iovec)); aiov.iov_base = rwcmd.bufaddr; aiov.iov_len = rwcmd.buflen; bzero((caddr_t)&auio, sizeof (struct uio)); auio.uio_iov = &aiov; auio.uio_iovcnt = 1; auio.uio_loffset = rwcmd.blkaddr * DEV_BSIZE; auio.uio_resid = rwcmd.buflen; auio.uio_segflg = flag & FKIOCTL ? UIO_SYSSPACE : UIO_USERSPACE; buf = kmem_alloc(sizeof (buf_t), KM_SLEEP); bioinit(buf); /* * We use the private field of buf to specify that this is an * I/O using an absolute offset. */ buf->b_private = (void *)VD_SLICE_NONE; status = physio(vdc_strategy, buf, dev, rw, vdc_min, &auio); biofini(buf); kmem_free(buf, sizeof (buf_t)); return (status); } /* * Allocate a buffer for a VD_OP_SCSICMD operation. The size of the allocated * buffer is returned in alloc_len. */ static vd_scsi_t * vdc_scsi_alloc(int cdb_len, int sense_len, int datain_len, int dataout_len, int *alloc_len) { vd_scsi_t *vd_scsi; int vd_scsi_len = VD_SCSI_SIZE; vd_scsi_len += P2ROUNDUP(cdb_len, sizeof (uint64_t)); vd_scsi_len += P2ROUNDUP(sense_len, sizeof (uint64_t)); vd_scsi_len += P2ROUNDUP(datain_len, sizeof (uint64_t)); vd_scsi_len += P2ROUNDUP(dataout_len, sizeof (uint64_t)); ASSERT(vd_scsi_len % sizeof (uint64_t) == 0); vd_scsi = kmem_zalloc(vd_scsi_len, KM_SLEEP); vd_scsi->cdb_len = cdb_len; vd_scsi->sense_len = sense_len; vd_scsi->datain_len = datain_len; vd_scsi->dataout_len = dataout_len; *alloc_len = vd_scsi_len; return (vd_scsi); } /* * Convert the status of a SCSI command to a Solaris return code. * * Arguments: * vd_scsi - The SCSI operation buffer. * log_error - indicate if an error message should be logged. * * Note that our SCSI error messages are rather primitive for the moment * and could be improved by decoding some data like the SCSI command and * the sense key. * * Return value: * 0 - Status is good. * EACCES - Status reports a reservation conflict. * ENOTSUP - Status reports a check condition and sense key * reports an illegal request. * EIO - Any other status. */ static int vdc_scsi_status(vdc_t *vdc, vd_scsi_t *vd_scsi, boolean_t log_error) { int rv; char path_str[MAXPATHLEN]; char panic_str[VDC_RESV_CONFLICT_FMT_LEN + MAXPATHLEN]; union scsi_cdb *cdb; struct scsi_extended_sense *sense; if (vd_scsi->cmd_status == STATUS_GOOD) /* no error */ return (0); /* when the tunable vdc_scsi_log_error is true we log all errors */ if (vdc_scsi_log_error) log_error = B_TRUE; if (log_error) { cmn_err(CE_WARN, "%s (vdc%d):\tError for Command: 0x%x)\n", ddi_pathname(vdc->dip, path_str), vdc->instance, GETCMD(VD_SCSI_DATA_CDB(vd_scsi))); } /* default returned value */ rv = EIO; switch (vd_scsi->cmd_status) { case STATUS_CHECK: case STATUS_TERMINATED: if (log_error) cmn_err(CE_CONT, "\tCheck Condition Error\n"); /* check sense buffer */ if (vd_scsi->sense_len == 0 || vd_scsi->sense_status != STATUS_GOOD) { if (log_error) cmn_err(CE_CONT, "\tNo Sense Data Available\n"); break; } sense = VD_SCSI_DATA_SENSE(vd_scsi); if (log_error) { cmn_err(CE_CONT, "\tSense Key: 0x%x\n" "\tASC: 0x%x, ASCQ: 0x%x\n", scsi_sense_key((uint8_t *)sense), scsi_sense_asc((uint8_t *)sense), scsi_sense_ascq((uint8_t *)sense)); } if (scsi_sense_key((uint8_t *)sense) == KEY_ILLEGAL_REQUEST) rv = ENOTSUP; break; case STATUS_BUSY: if (log_error) cmn_err(CE_NOTE, "\tDevice Busy\n"); break; case STATUS_RESERVATION_CONFLICT: /* * If the command was PERSISTENT_RESERVATION_[IN|OUT] then * reservation conflict could be due to various reasons like * incorrect keys, not registered or not reserved etc. So, * we should not panic in that case. */ cdb = VD_SCSI_DATA_CDB(vd_scsi); if (vdc->failfast_interval != 0 && cdb->scc_cmd != SCMD_PERSISTENT_RESERVE_IN && cdb->scc_cmd != SCMD_PERSISTENT_RESERVE_OUT) { /* failfast is enabled so we have to panic */ (void) snprintf(panic_str, sizeof (panic_str), VDC_RESV_CONFLICT_FMT_STR "%s", ddi_pathname(vdc->dip, path_str)); panic(panic_str); } if (log_error) cmn_err(CE_NOTE, "\tReservation Conflict\n"); rv = EACCES; break; case STATUS_QFULL: if (log_error) cmn_err(CE_NOTE, "\tQueue Full\n"); break; case STATUS_MET: case STATUS_INTERMEDIATE: case STATUS_SCSI2: case STATUS_INTERMEDIATE_MET: case STATUS_ACA_ACTIVE: if (log_error) cmn_err(CE_CONT, "\tUnexpected SCSI status received: 0x%x\n", vd_scsi->cmd_status); break; default: if (log_error) cmn_err(CE_CONT, "\tInvalid SCSI status received: 0x%x\n", vd_scsi->cmd_status); break; } return (rv); } /* * Implemented the USCSICMD uscsi(7I) ioctl. This ioctl is converted to * a VD_OP_SCSICMD operation which is sent to the vdisk server. If a SCSI * reset is requested (i.e. a flag USCSI_RESET* is set) then the ioctl is * converted to a VD_OP_RESET operation. */ static int vdc_uscsi_cmd(vdc_t *vdc, caddr_t arg, int mode) { struct uscsi_cmd uscsi; struct uscsi_cmd32 uscsi32; vd_scsi_t *vd_scsi; int vd_scsi_len; union scsi_cdb *cdb; struct scsi_extended_sense *sense; char *datain, *dataout; size_t cdb_len, datain_len, dataout_len, sense_len; int rv; if (ddi_model_convert_from(mode & FMODELS) == DDI_MODEL_ILP32) { if (ddi_copyin(arg, &uscsi32, sizeof (struct uscsi_cmd32), mode) != 0) return (EFAULT); uscsi_cmd32touscsi_cmd((&uscsi32), (&uscsi)); } else { if (ddi_copyin(arg, &uscsi, sizeof (struct uscsi_cmd), mode) != 0) return (EFAULT); } /* a uscsi reset is converted to a VD_OP_RESET operation */ if (uscsi.uscsi_flags & (USCSI_RESET | USCSI_RESET_LUN | USCSI_RESET_ALL)) { rv = vdc_do_sync_op(vdc, VD_OP_RESET, NULL, 0, 0, 0, CB_SYNC, (void *)(uint64_t)mode, VIO_both_dir, B_TRUE); return (rv); } /* cdb buffer length */ cdb_len = uscsi.uscsi_cdblen; /* data in and out buffers length */ if (uscsi.uscsi_flags & USCSI_READ) { datain_len = uscsi.uscsi_buflen; dataout_len = 0; } else { datain_len = 0; dataout_len = uscsi.uscsi_buflen; } /* sense buffer length */ if (uscsi.uscsi_flags & USCSI_RQENABLE) sense_len = uscsi.uscsi_rqlen; else sense_len = 0; /* allocate buffer for the VD_SCSICMD_OP operation */ vd_scsi = vdc_scsi_alloc(cdb_len, sense_len, datain_len, dataout_len, &vd_scsi_len); /* * The documentation of USCSI_ISOLATE and USCSI_DIAGNOSE is very vague, * but basically they prevent a SCSI command from being retried in case * of an error. */ if ((uscsi.uscsi_flags & USCSI_ISOLATE) || (uscsi.uscsi_flags & USCSI_DIAGNOSE)) vd_scsi->options |= VD_SCSI_OPT_NORETRY; /* set task attribute */ if (uscsi.uscsi_flags & USCSI_NOTAG) { vd_scsi->task_attribute = 0; } else { if (uscsi.uscsi_flags & USCSI_HEAD) vd_scsi->task_attribute = VD_SCSI_TASK_ACA; else if (uscsi.uscsi_flags & USCSI_HTAG) vd_scsi->task_attribute = VD_SCSI_TASK_HQUEUE; else if (uscsi.uscsi_flags & USCSI_OTAG) vd_scsi->task_attribute = VD_SCSI_TASK_ORDERED; else vd_scsi->task_attribute = 0; } /* set timeout */ vd_scsi->timeout = uscsi.uscsi_timeout; /* copy-in cdb data */ cdb = VD_SCSI_DATA_CDB(vd_scsi); if (ddi_copyin(uscsi.uscsi_cdb, cdb, cdb_len, mode) != 0) { rv = EFAULT; goto done; } /* keep a pointer to the sense buffer */ sense = VD_SCSI_DATA_SENSE(vd_scsi); /* keep a pointer to the data-in buffer */ datain = (char *)VD_SCSI_DATA_IN(vd_scsi); /* copy-in request data to the data-out buffer */ dataout = (char *)VD_SCSI_DATA_OUT(vd_scsi); if (!(uscsi.uscsi_flags & USCSI_READ)) { if (ddi_copyin(uscsi.uscsi_bufaddr, dataout, dataout_len, mode)) { rv = EFAULT; goto done; } } /* submit the request */ rv = vdc_do_sync_op(vdc, VD_OP_SCSICMD, (caddr_t)vd_scsi, vd_scsi_len, 0, 0, CB_SYNC, (void *)(uint64_t)mode, VIO_both_dir, B_FALSE); if (rv != 0) goto done; /* update scsi status */ uscsi.uscsi_status = vd_scsi->cmd_status; /* update sense data */ if ((uscsi.uscsi_flags & USCSI_RQENABLE) && (uscsi.uscsi_status == STATUS_CHECK || uscsi.uscsi_status == STATUS_TERMINATED)) { uscsi.uscsi_rqstatus = vd_scsi->sense_status; if (uscsi.uscsi_rqstatus == STATUS_GOOD) { uscsi.uscsi_rqresid = uscsi.uscsi_rqlen - vd_scsi->sense_len; if (ddi_copyout(sense, uscsi.uscsi_rqbuf, vd_scsi->sense_len, mode) != 0) { rv = EFAULT; goto done; } } } /* update request data */ if (uscsi.uscsi_status == STATUS_GOOD) { if (uscsi.uscsi_flags & USCSI_READ) { uscsi.uscsi_resid = uscsi.uscsi_buflen - vd_scsi->datain_len; if (ddi_copyout(datain, uscsi.uscsi_bufaddr, vd_scsi->datain_len, mode) != 0) { rv = EFAULT; goto done; } } else { uscsi.uscsi_resid = uscsi.uscsi_buflen - vd_scsi->dataout_len; } } /* copy-out result */ if (ddi_model_convert_from(mode & FMODELS) == DDI_MODEL_ILP32) { uscsi_cmdtouscsi_cmd32((&uscsi), (&uscsi32)); if (ddi_copyout(&uscsi32, arg, sizeof (struct uscsi_cmd32), mode) != 0) { rv = EFAULT; goto done; } } else { if (ddi_copyout(&uscsi, arg, sizeof (struct uscsi_cmd), mode) != 0) { rv = EFAULT; goto done; } } /* get the return code from the SCSI command status */ rv = vdc_scsi_status(vdc, vd_scsi, !(uscsi.uscsi_flags & USCSI_SILENT)); done: kmem_free(vd_scsi, vd_scsi_len); return (rv); } /* * Create a VD_OP_SCSICMD buffer for a SCSI PERSISTENT IN command. * * Arguments: * cmd - SCSI PERSISTENT IN command * len - length of the SCSI input buffer * vd_scsi_len - return the length of the allocated buffer * * Returned Value: * a pointer to the allocated VD_OP_SCSICMD buffer. */ static vd_scsi_t * vdc_scsi_alloc_persistent_in(uchar_t cmd, int len, int *vd_scsi_len) { int cdb_len, sense_len, datain_len, dataout_len; vd_scsi_t *vd_scsi; union scsi_cdb *cdb; cdb_len = CDB_GROUP1; sense_len = sizeof (struct scsi_extended_sense); datain_len = len; dataout_len = 0; vd_scsi = vdc_scsi_alloc(cdb_len, sense_len, datain_len, dataout_len, vd_scsi_len); cdb = VD_SCSI_DATA_CDB(vd_scsi); /* set cdb */ cdb->scc_cmd = SCMD_PERSISTENT_RESERVE_IN; cdb->cdb_opaque[1] = cmd; FORMG1COUNT(cdb, datain_len); vd_scsi->timeout = vdc_scsi_timeout; return (vd_scsi); } /* * Create a VD_OP_SCSICMD buffer for a SCSI PERSISTENT OUT command. * * Arguments: * cmd - SCSI PERSISTENT OUT command * len - length of the SCSI output buffer * vd_scsi_len - return the length of the allocated buffer * * Returned Code: * a pointer to the allocated VD_OP_SCSICMD buffer. */ static vd_scsi_t * vdc_scsi_alloc_persistent_out(uchar_t cmd, int len, int *vd_scsi_len) { int cdb_len, sense_len, datain_len, dataout_len; vd_scsi_t *vd_scsi; union scsi_cdb *cdb; cdb_len = CDB_GROUP1; sense_len = sizeof (struct scsi_extended_sense); datain_len = 0; dataout_len = len; vd_scsi = vdc_scsi_alloc(cdb_len, sense_len, datain_len, dataout_len, vd_scsi_len); cdb = VD_SCSI_DATA_CDB(vd_scsi); /* set cdb */ cdb->scc_cmd = SCMD_PERSISTENT_RESERVE_OUT; cdb->cdb_opaque[1] = cmd; FORMG1COUNT(cdb, dataout_len); vd_scsi->timeout = vdc_scsi_timeout; return (vd_scsi); } /* * Implement the MHIOCGRP_INKEYS mhd(7i) ioctl. The ioctl is converted * to a SCSI PERSISTENT IN READ KEYS command which is sent to the vdisk * server with a VD_OP_SCSICMD operation. */ static int vdc_mhd_inkeys(vdc_t *vdc, caddr_t arg, int mode) { vd_scsi_t *vd_scsi; mhioc_inkeys_t inkeys; mhioc_key_list_t klist; struct mhioc_inkeys32 inkeys32; struct mhioc_key_list32 klist32; sd_prin_readkeys_t *scsi_keys; void *user_keys; int vd_scsi_len; int listsize, listlen, rv; /* copyin arguments */ if (ddi_model_convert_from(mode & FMODELS) == DDI_MODEL_ILP32) { rv = ddi_copyin(arg, &inkeys32, sizeof (inkeys32), mode); if (rv != 0) return (EFAULT); rv = ddi_copyin((caddr_t)(uintptr_t)inkeys32.li, &klist32, sizeof (klist32), mode); if (rv != 0) return (EFAULT); listsize = klist32.listsize; } else { rv = ddi_copyin(arg, &inkeys, sizeof (inkeys), mode); if (rv != 0) return (EFAULT); rv = ddi_copyin(inkeys.li, &klist, sizeof (klist), mode); if (rv != 0) return (EFAULT); listsize = klist.listsize; } /* build SCSI VD_OP request */ vd_scsi = vdc_scsi_alloc_persistent_in(SD_READ_KEYS, sizeof (sd_prin_readkeys_t) - sizeof (caddr_t) + (sizeof (mhioc_resv_key_t) * listsize), &vd_scsi_len); scsi_keys = (sd_prin_readkeys_t *)VD_SCSI_DATA_IN(vd_scsi); /* submit the request */ rv = vdc_do_sync_op(vdc, VD_OP_SCSICMD, (caddr_t)vd_scsi, vd_scsi_len, 0, 0, CB_SYNC, (void *)(uint64_t)mode, VIO_both_dir, B_FALSE); if (rv != 0) goto done; listlen = scsi_keys->len / MHIOC_RESV_KEY_SIZE; if (ddi_model_convert_from(mode & FMODELS) == DDI_MODEL_ILP32) { inkeys32.generation = scsi_keys->generation; rv = ddi_copyout(&inkeys32, arg, sizeof (inkeys32), mode); if (rv != 0) { rv = EFAULT; goto done; } klist32.listlen = listlen; rv = ddi_copyout(&klist32, (caddr_t)(uintptr_t)inkeys32.li, sizeof (klist32), mode); if (rv != 0) { rv = EFAULT; goto done; } user_keys = (caddr_t)(uintptr_t)klist32.list; } else { inkeys.generation = scsi_keys->generation; rv = ddi_copyout(&inkeys, arg, sizeof (inkeys), mode); if (rv != 0) { rv = EFAULT; goto done; } klist.listlen = listlen; rv = ddi_copyout(&klist, inkeys.li, sizeof (klist), mode); if (rv != 0) { rv = EFAULT; goto done; } user_keys = klist.list; } /* copy out keys */ if (listlen > 0 && listsize > 0) { if (listsize < listlen) listlen = listsize; rv = ddi_copyout(&scsi_keys->keylist, user_keys, listlen * MHIOC_RESV_KEY_SIZE, mode); if (rv != 0) rv = EFAULT; } if (rv == 0) rv = vdc_scsi_status(vdc, vd_scsi, B_FALSE); done: kmem_free(vd_scsi, vd_scsi_len); return (rv); } /* * Implement the MHIOCGRP_INRESV mhd(7i) ioctl. The ioctl is converted * to a SCSI PERSISTENT IN READ RESERVATION command which is sent to * the vdisk server with a VD_OP_SCSICMD operation. */ static int vdc_mhd_inresv(vdc_t *vdc, caddr_t arg, int mode) { vd_scsi_t *vd_scsi; mhioc_inresvs_t inresv; mhioc_resv_desc_list_t rlist; struct mhioc_inresvs32 inresv32; struct mhioc_resv_desc_list32 rlist32; mhioc_resv_desc_t mhd_resv; sd_prin_readresv_t *scsi_resv; sd_readresv_desc_t *resv; mhioc_resv_desc_t *user_resv; int vd_scsi_len; int listsize, listlen, i, rv; /* copyin arguments */ if (ddi_model_convert_from(mode & FMODELS) == DDI_MODEL_ILP32) { rv = ddi_copyin(arg, &inresv32, sizeof (inresv32), mode); if (rv != 0) return (EFAULT); rv = ddi_copyin((caddr_t)(uintptr_t)inresv32.li, &rlist32, sizeof (rlist32), mode); if (rv != 0) return (EFAULT); listsize = rlist32.listsize; } else { rv = ddi_copyin(arg, &inresv, sizeof (inresv), mode); if (rv != 0) return (EFAULT); rv = ddi_copyin(inresv.li, &rlist, sizeof (rlist), mode); if (rv != 0) return (EFAULT); listsize = rlist.listsize; } /* build SCSI VD_OP request */ vd_scsi = vdc_scsi_alloc_persistent_in(SD_READ_RESV, sizeof (sd_prin_readresv_t) - sizeof (caddr_t) + (SCSI3_RESV_DESC_LEN * listsize), &vd_scsi_len); scsi_resv = (sd_prin_readresv_t *)VD_SCSI_DATA_IN(vd_scsi); /* submit the request */ rv = vdc_do_sync_op(vdc, VD_OP_SCSICMD, (caddr_t)vd_scsi, vd_scsi_len, 0, 0, CB_SYNC, (void *)(uint64_t)mode, VIO_both_dir, B_FALSE); if (rv != 0) goto done; listlen = scsi_resv->len / SCSI3_RESV_DESC_LEN; if (ddi_model_convert_from(mode & FMODELS) == DDI_MODEL_ILP32) { inresv32.generation = scsi_resv->generation; rv = ddi_copyout(&inresv32, arg, sizeof (inresv32), mode); if (rv != 0) { rv = EFAULT; goto done; } rlist32.listlen = listlen; rv = ddi_copyout(&rlist32, (caddr_t)(uintptr_t)inresv32.li, sizeof (rlist32), mode); if (rv != 0) { rv = EFAULT; goto done; } user_resv = (mhioc_resv_desc_t *)(uintptr_t)rlist32.list; } else { inresv.generation = scsi_resv->generation; rv = ddi_copyout(&inresv, arg, sizeof (inresv), mode); if (rv != 0) { rv = EFAULT; goto done; } rlist.listlen = listlen; rv = ddi_copyout(&rlist, inresv.li, sizeof (rlist), mode); if (rv != 0) { rv = EFAULT; goto done; } user_resv = rlist.list; } /* copy out reservations */ if (listsize > 0 && listlen > 0) { if (listsize < listlen) listlen = listsize; resv = (sd_readresv_desc_t *)&scsi_resv->readresv_desc; for (i = 0; i < listlen; i++) { mhd_resv.type = resv->type; mhd_resv.scope = resv->scope; mhd_resv.scope_specific_addr = BE_32(resv->scope_specific_addr); bcopy(&resv->resvkey, &mhd_resv.key, MHIOC_RESV_KEY_SIZE); rv = ddi_copyout(&mhd_resv, user_resv, sizeof (mhd_resv), mode); if (rv != 0) { rv = EFAULT; goto done; } resv++; user_resv++; } } if (rv == 0) rv = vdc_scsi_status(vdc, vd_scsi, B_FALSE); done: kmem_free(vd_scsi, vd_scsi_len); return (rv); } /* * Implement the MHIOCGRP_REGISTER mhd(7i) ioctl. The ioctl is converted * to a SCSI PERSISTENT OUT REGISTER command which is sent to the vdisk * server with a VD_OP_SCSICMD operation. */ static int vdc_mhd_register(vdc_t *vdc, caddr_t arg, int mode) { vd_scsi_t *vd_scsi; sd_prout_t *scsi_prout; mhioc_register_t mhd_reg; int vd_scsi_len, rv; /* copyin arguments */ rv = ddi_copyin(arg, &mhd_reg, sizeof (mhd_reg), mode); if (rv != 0) return (EFAULT); /* build SCSI VD_OP request */ vd_scsi = vdc_scsi_alloc_persistent_out(SD_SCSI3_REGISTER, sizeof (sd_prout_t), &vd_scsi_len); /* set parameters */ scsi_prout = (sd_prout_t *)VD_SCSI_DATA_OUT(vd_scsi); bcopy(mhd_reg.oldkey.key, scsi_prout->res_key, MHIOC_RESV_KEY_SIZE); bcopy(mhd_reg.newkey.key, scsi_prout->service_key, MHIOC_RESV_KEY_SIZE); scsi_prout->aptpl = (uchar_t)mhd_reg.aptpl; /* submit the request */ rv = vdc_do_sync_op(vdc, VD_OP_SCSICMD, (caddr_t)vd_scsi, vd_scsi_len, 0, 0, CB_SYNC, (void *)(uint64_t)mode, VIO_both_dir, B_FALSE); if (rv == 0) rv = vdc_scsi_status(vdc, vd_scsi, B_FALSE); kmem_free(vd_scsi, vd_scsi_len); return (rv); } /* * Implement the MHIOCGRP_RESERVE mhd(7i) ioctl. The ioctl is converted * to a SCSI PERSISTENT OUT RESERVE command which is sent to the vdisk * server with a VD_OP_SCSICMD operation. */ static int vdc_mhd_reserve(vdc_t *vdc, caddr_t arg, int mode) { union scsi_cdb *cdb; vd_scsi_t *vd_scsi; sd_prout_t *scsi_prout; mhioc_resv_desc_t mhd_resv; int vd_scsi_len, rv; /* copyin arguments */ rv = ddi_copyin(arg, &mhd_resv, sizeof (mhd_resv), mode); if (rv != 0) return (EFAULT); /* build SCSI VD_OP request */ vd_scsi = vdc_scsi_alloc_persistent_out(SD_SCSI3_RESERVE, sizeof (sd_prout_t), &vd_scsi_len); /* set parameters */ cdb = VD_SCSI_DATA_CDB(vd_scsi); scsi_prout = (sd_prout_t *)VD_SCSI_DATA_OUT(vd_scsi); bcopy(mhd_resv.key.key, scsi_prout->res_key, MHIOC_RESV_KEY_SIZE); scsi_prout->scope_address = mhd_resv.scope_specific_addr; cdb->cdb_opaque[2] = mhd_resv.type; /* submit the request */ rv = vdc_do_sync_op(vdc, VD_OP_SCSICMD, (caddr_t)vd_scsi, vd_scsi_len, 0, 0, CB_SYNC, (void *)(uint64_t)mode, VIO_both_dir, B_FALSE); if (rv == 0) rv = vdc_scsi_status(vdc, vd_scsi, B_FALSE); kmem_free(vd_scsi, vd_scsi_len); return (rv); } /* * Implement the MHIOCGRP_PREEMPTANDABORT mhd(7i) ioctl. The ioctl is * converted to a SCSI PERSISTENT OUT PREEMPT AND ABORT command which * is sent to the vdisk server with a VD_OP_SCSICMD operation. */ static int vdc_mhd_preemptabort(vdc_t *vdc, caddr_t arg, int mode) { union scsi_cdb *cdb; vd_scsi_t *vd_scsi; sd_prout_t *scsi_prout; mhioc_preemptandabort_t mhd_preempt; int vd_scsi_len, rv; /* copyin arguments */ rv = ddi_copyin(arg, &mhd_preempt, sizeof (mhd_preempt), mode); if (rv != 0) return (EFAULT); /* build SCSI VD_OP request */ vd_scsi = vdc_scsi_alloc_persistent_out(SD_SCSI3_PREEMPTANDABORT, sizeof (sd_prout_t), &vd_scsi_len); /* set parameters */ vd_scsi->task_attribute = VD_SCSI_TASK_ACA; cdb = VD_SCSI_DATA_CDB(vd_scsi); scsi_prout = (sd_prout_t *)VD_SCSI_DATA_OUT(vd_scsi); bcopy(mhd_preempt.resvdesc.key.key, scsi_prout->res_key, MHIOC_RESV_KEY_SIZE); bcopy(mhd_preempt.victim_key.key, scsi_prout->service_key, MHIOC_RESV_KEY_SIZE); scsi_prout->scope_address = mhd_preempt.resvdesc.scope_specific_addr; cdb->cdb_opaque[2] = mhd_preempt.resvdesc.type; /* submit the request */ rv = vdc_do_sync_op(vdc, VD_OP_SCSICMD, (caddr_t)vd_scsi, vd_scsi_len, 0, 0, CB_SYNC, (void *)(uint64_t)mode, VIO_both_dir, B_FALSE); if (rv == 0) rv = vdc_scsi_status(vdc, vd_scsi, B_FALSE); kmem_free(vd_scsi, vd_scsi_len); return (rv); } /* * Implement the MHIOCGRP_REGISTERANDIGNOREKEY mhd(7i) ioctl. The ioctl * is converted to a SCSI PERSISTENT OUT REGISTER AND IGNORE EXISTING KEY * command which is sent to the vdisk server with a VD_OP_SCSICMD operation. */ static int vdc_mhd_registerignore(vdc_t *vdc, caddr_t arg, int mode) { vd_scsi_t *vd_scsi; sd_prout_t *scsi_prout; mhioc_registerandignorekey_t mhd_regi; int vd_scsi_len, rv; /* copyin arguments */ rv = ddi_copyin(arg, &mhd_regi, sizeof (mhd_regi), mode); if (rv != 0) return (EFAULT); /* build SCSI VD_OP request */ vd_scsi = vdc_scsi_alloc_persistent_out(SD_SCSI3_REGISTERANDIGNOREKEY, sizeof (sd_prout_t), &vd_scsi_len); /* set parameters */ scsi_prout = (sd_prout_t *)VD_SCSI_DATA_OUT(vd_scsi); bcopy(mhd_regi.newkey.key, scsi_prout->service_key, MHIOC_RESV_KEY_SIZE); scsi_prout->aptpl = (uchar_t)mhd_regi.aptpl; /* submit the request */ rv = vdc_do_sync_op(vdc, VD_OP_SCSICMD, (caddr_t)vd_scsi, vd_scsi_len, 0, 0, CB_SYNC, (void *)(uint64_t)mode, VIO_both_dir, B_FALSE); if (rv == 0) rv = vdc_scsi_status(vdc, vd_scsi, B_FALSE); kmem_free(vd_scsi, vd_scsi_len); return (rv); } /* * This function is used by the failfast mechanism to send a SCSI command * to check for reservation conflict. */ static int vdc_failfast_scsi_cmd(vdc_t *vdc, uchar_t scmd) { int cdb_len, sense_len, vd_scsi_len; vd_scsi_t *vd_scsi; union scsi_cdb *cdb; int rv; ASSERT(scmd == SCMD_TEST_UNIT_READY || scmd == SCMD_WRITE_G1); if (scmd == SCMD_WRITE_G1) cdb_len = CDB_GROUP1; else cdb_len = CDB_GROUP0; sense_len = sizeof (struct scsi_extended_sense); vd_scsi = vdc_scsi_alloc(cdb_len, sense_len, 0, 0, &vd_scsi_len); /* set cdb */ cdb = VD_SCSI_DATA_CDB(vd_scsi); cdb->scc_cmd = scmd; vd_scsi->timeout = vdc_scsi_timeout; /* * Submit the request. The last argument has to be B_FALSE so that * vdc_do_sync_op does not loop checking for reservation conflict if * the operation returns an error. */ rv = vdc_do_sync_op(vdc, VD_OP_SCSICMD, (caddr_t)vd_scsi, vd_scsi_len, 0, 0, CB_SYNC, (void *)(uint64_t)FKIOCTL, VIO_both_dir, B_FALSE); if (rv == 0) (void) vdc_scsi_status(vdc, vd_scsi, B_FALSE); kmem_free(vd_scsi, vd_scsi_len); return (rv); } /* * This function is used by the failfast mechanism to check for reservation * conflict. It sends some SCSI commands which will fail with a reservation * conflict error if the system does not have access to the disk and this * will panic the system. * * Returned Code: * 0 - disk is accessible without reservation conflict error * != 0 - unable to check if disk is accessible */ int vdc_failfast_check_resv(vdc_t *vdc) { int failure = 0; /* * Send a TEST UNIT READY command. The command will panic * the system if it fails with a reservation conflict. */ if (vdc_failfast_scsi_cmd(vdc, SCMD_TEST_UNIT_READY) != 0) failure++; /* * With SPC-3 compliant devices TEST UNIT READY will succeed on * a reserved device, so we also do a WRITE(10) of zero byte in * order to provoke a Reservation Conflict status on those newer * devices. */ if (vdc_failfast_scsi_cmd(vdc, SCMD_WRITE_G1) != 0) failure++; return (failure); } /* * Add a pending I/O to the failfast I/O queue. An I/O is added to this * queue when it has failed and failfast is enabled. Then we have to check * if it has failed because of a reservation conflict in which case we have * to panic the system. * * Async I/O should be queued with their block I/O data transfer structure * (buf). Sync I/O should be queued with buf = NULL. */ static vdc_io_t * vdc_failfast_io_queue(vdc_t *vdc, struct buf *buf) { vdc_io_t *vio; ASSERT(MUTEX_HELD(&vdc->lock)); vio = kmem_alloc(sizeof (vdc_io_t), KM_SLEEP); vio->vio_next = vdc->failfast_io_queue; vio->vio_buf = buf; vio->vio_qtime = ddi_get_lbolt(); vdc->failfast_io_queue = vio; /* notify the failfast thread that a new I/O is queued */ cv_signal(&vdc->failfast_cv); return (vio); } /* * Remove and complete I/O in the failfast I/O queue which have been * added after the indicated deadline. A deadline of 0 means that all * I/O have to be unqueued and marked as completed. */ static void vdc_failfast_io_unqueue(vdc_t *vdc, clock_t deadline) { vdc_io_t *vio, *vio_tmp; ASSERT(MUTEX_HELD(&vdc->lock)); vio_tmp = NULL; vio = vdc->failfast_io_queue; if (deadline != 0) { /* * Skip any io queued after the deadline. The failfast * I/O queue is ordered starting with the last I/O added * to the queue. */ while (vio != NULL && vio->vio_qtime > deadline) { vio_tmp = vio; vio = vio->vio_next; } } if (vio == NULL) /* nothing to unqueue */ return; /* update the queue */ if (vio_tmp == NULL) vdc->failfast_io_queue = NULL; else vio_tmp->vio_next = NULL; /* * Complete unqueued I/O. Async I/O have a block I/O data transfer * structure (buf) and they are completed by calling biodone(). Sync * I/O do not have a buf and they are completed by setting the * vio_qtime to zero and signaling failfast_io_cv. In that case, the * thread waiting for the I/O to complete is responsible for freeing * the vio structure. */ while (vio != NULL) { vio_tmp = vio->vio_next; if (vio->vio_buf != NULL) { biodone(vio->vio_buf); kmem_free(vio, sizeof (vdc_io_t)); } else { vio->vio_qtime = 0; } vio = vio_tmp; } cv_broadcast(&vdc->failfast_io_cv); } /* * Failfast Thread. * * While failfast is enabled, the failfast thread sends a TEST UNIT READY * and a zero size WRITE(10) SCSI commands on a regular basis to check that * we still have access to the disk. If a command fails with a RESERVATION * CONFLICT error then the system will immediatly panic. * * The failfast thread is also woken up when an I/O has failed. It then check * the access to the disk to ensure that the I/O failure was not due to a * reservation conflict. * * There is one failfast thread for each virtual disk for which failfast is * enabled. We could have only one thread sending requests for all disks but * this would need vdc to send asynchronous requests and to have callbacks to * process replies. */ static void vdc_failfast_thread(void *arg) { int status; vdc_t *vdc = (vdc_t *)arg; clock_t timeout, starttime; mutex_enter(&vdc->lock); while (vdc->failfast_interval != 0) { starttime = ddi_get_lbolt(); mutex_exit(&vdc->lock); /* check for reservation conflict */ status = vdc_failfast_check_resv(vdc); mutex_enter(&vdc->lock); /* * We have dropped the lock to send the SCSI command so we have * to check that failfast is still enabled. */ if (vdc->failfast_interval == 0) break; /* * If we have successfully check the disk access and there was * no reservation conflict then we can complete any I/O queued * before the last check. */ if (status == 0) vdc_failfast_io_unqueue(vdc, starttime); /* proceed again if some I/O are still in the queue */ if (vdc->failfast_io_queue != NULL) continue; timeout = ddi_get_lbolt() + drv_usectohz(vdc->failfast_interval); (void) cv_timedwait(&vdc->failfast_cv, &vdc->lock, timeout); } /* * Failfast is being stop so we can complete any queued I/O. */ vdc_failfast_io_unqueue(vdc, 0); vdc->failfast_thread = NULL; mutex_exit(&vdc->lock); thread_exit(); } /* * Implement the MHIOCENFAILFAST mhd(7i) ioctl. */ static int vdc_failfast(vdc_t *vdc, caddr_t arg, int mode) { unsigned int mh_time; if (ddi_copyin((void *)arg, &mh_time, sizeof (int), mode)) return (EFAULT); mutex_enter(&vdc->lock); if (mh_time != 0 && vdc->failfast_thread == NULL) { vdc->failfast_thread = thread_create(NULL, 0, vdc_failfast_thread, vdc, 0, &p0, TS_RUN, v.v_maxsyspri - 2); } vdc->failfast_interval = mh_time * 1000; cv_signal(&vdc->failfast_cv); mutex_exit(&vdc->lock); return (0); } /* * Implement the MHIOCTKOWN and MHIOCRELEASE mhd(7i) ioctls. These ioctls are * converted to VD_OP_SET_ACCESS operations. */ static int vdc_access_set(vdc_t *vdc, uint64_t flags, int mode) { int rv; /* submit owership command request */ rv = vdc_do_sync_op(vdc, VD_OP_SET_ACCESS, (caddr_t)&flags, sizeof (uint64_t), 0, 0, CB_SYNC, (void *)(uint64_t)mode, VIO_both_dir, B_TRUE); return (rv); } /* * Implement the MHIOCSTATUS mhd(7i) ioctl. This ioctl is converted to a * VD_OP_GET_ACCESS operation. */ static int vdc_access_get(vdc_t *vdc, uint64_t *status, int mode) { int rv; /* submit owership command request */ rv = vdc_do_sync_op(vdc, VD_OP_GET_ACCESS, (caddr_t)status, sizeof (uint64_t), 0, 0, CB_SYNC, (void *)(uint64_t)mode, VIO_both_dir, B_TRUE); return (rv); } /* * Disk Ownership Thread. * * When we have taken the ownership of a disk, this thread waits to be * notified when the LDC channel is reset so that it can recover the * ownership. * * Note that the thread handling the LDC reset (vdc_process_msg_thread()) * can not be used to do the ownership recovery because it has to be * running to handle the reply message to the ownership operation. */ static void vdc_ownership_thread(void *arg) { vdc_t *vdc = (vdc_t *)arg; clock_t timeout; uint64_t status; mutex_enter(&vdc->ownership_lock); mutex_enter(&vdc->lock); while (vdc->ownership & VDC_OWNERSHIP_WANTED) { if ((vdc->ownership & VDC_OWNERSHIP_RESET) || !(vdc->ownership & VDC_OWNERSHIP_GRANTED)) { /* * There was a reset so the ownership has been lost, * try to recover. We do this without using the preempt * option so that we don't steal the ownership from * someone who has preempted us. */ DMSG(vdc, 0, "[%d] Ownership lost, recovering", vdc->instance); vdc->ownership &= ~(VDC_OWNERSHIP_RESET | VDC_OWNERSHIP_GRANTED); mutex_exit(&vdc->lock); status = vdc_access_set(vdc, VD_ACCESS_SET_EXCLUSIVE | VD_ACCESS_SET_PRESERVE, FKIOCTL); mutex_enter(&vdc->lock); if (status == 0) { DMSG(vdc, 0, "[%d] Ownership recovered", vdc->instance); vdc->ownership |= VDC_OWNERSHIP_GRANTED; } else { DMSG(vdc, 0, "[%d] Fail to recover ownership", vdc->instance); } } /* * If we have the ownership then we just wait for an event * to happen (LDC reset), otherwise we will retry to recover * after a delay. */ if (vdc->ownership & VDC_OWNERSHIP_GRANTED) timeout = 0; else timeout = ddi_get_lbolt() + drv_usectohz(vdc_ownership_delay); /* Release the ownership_lock and wait on the vdc lock */ mutex_exit(&vdc->ownership_lock); if (timeout == 0) (void) cv_wait(&vdc->ownership_cv, &vdc->lock); else (void) cv_timedwait(&vdc->ownership_cv, &vdc->lock, timeout); mutex_exit(&vdc->lock); mutex_enter(&vdc->ownership_lock); mutex_enter(&vdc->lock); } vdc->ownership_thread = NULL; mutex_exit(&vdc->lock); mutex_exit(&vdc->ownership_lock); thread_exit(); } static void vdc_ownership_update(vdc_t *vdc, int ownership_flags) { ASSERT(MUTEX_HELD(&vdc->ownership_lock)); mutex_enter(&vdc->lock); vdc->ownership = ownership_flags; if ((vdc->ownership & VDC_OWNERSHIP_WANTED) && vdc->ownership_thread == NULL) { /* start ownership thread */ vdc->ownership_thread = thread_create(NULL, 0, vdc_ownership_thread, vdc, 0, &p0, TS_RUN, v.v_maxsyspri - 2); } else { /* notify the ownership thread */ cv_signal(&vdc->ownership_cv); } mutex_exit(&vdc->lock); } /* * Get the size and the block size of a virtual disk from the vdisk server. * We need to use this operation when the vdisk_size attribute was not * available during the handshake with the vdisk server. */ static int vdc_check_capacity(vdc_t *vdc) { int rv = 0; size_t alloc_len; vd_capacity_t *vd_cap; if (vdc->vdisk_size != 0) return (0); alloc_len = P2ROUNDUP(sizeof (vd_capacity_t), sizeof (uint64_t)); vd_cap = kmem_zalloc(alloc_len, KM_SLEEP); rv = vdc_do_sync_op(vdc, VD_OP_GET_CAPACITY, (caddr_t)vd_cap, alloc_len, 0, 0, CB_SYNC, (void *)(uint64_t)FKIOCTL, VIO_both_dir, B_TRUE); if (rv == 0) { if (vd_cap->vdisk_block_size != vdc->block_size || vd_cap->vdisk_size == VD_SIZE_UNKNOWN || vd_cap->vdisk_size == 0) rv = EINVAL; else vdc->vdisk_size = vd_cap->vdisk_size; } kmem_free(vd_cap, alloc_len); return (rv); } /* * This structure is used in the DKIO(7I) array below. */ typedef struct vdc_dk_ioctl { uint8_t op; /* VD_OP_XXX value */ int cmd; /* Solaris ioctl operation number */ size_t nbytes; /* size of structure to be copied */ /* function to convert between vDisk and Solaris structure formats */ int (*convert)(vdc_t *vdc, void *vd_buf, void *ioctl_arg, int mode, int dir); } vdc_dk_ioctl_t; /* * Subset of DKIO(7I) operations currently supported */ static vdc_dk_ioctl_t dk_ioctl[] = { {VD_OP_FLUSH, DKIOCFLUSHWRITECACHE, 0, vdc_null_copy_func}, {VD_OP_GET_WCE, DKIOCGETWCE, sizeof (int), vdc_get_wce_convert}, {VD_OP_SET_WCE, DKIOCSETWCE, sizeof (int), vdc_set_wce_convert}, {VD_OP_GET_VTOC, DKIOCGVTOC, sizeof (vd_vtoc_t), vdc_get_vtoc_convert}, {VD_OP_SET_VTOC, DKIOCSVTOC, sizeof (vd_vtoc_t), vdc_set_vtoc_convert}, {VD_OP_GET_DISKGEOM, DKIOCGGEOM, sizeof (vd_geom_t), vdc_get_geom_convert}, {VD_OP_GET_DISKGEOM, DKIOCG_PHYGEOM, sizeof (vd_geom_t), vdc_get_geom_convert}, {VD_OP_GET_DISKGEOM, DKIOCG_VIRTGEOM, sizeof (vd_geom_t), vdc_get_geom_convert}, {VD_OP_SET_DISKGEOM, DKIOCSGEOM, sizeof (vd_geom_t), vdc_set_geom_convert}, {VD_OP_GET_EFI, DKIOCGETEFI, 0, vdc_get_efi_convert}, {VD_OP_SET_EFI, DKIOCSETEFI, 0, vdc_set_efi_convert}, /* DIOCTL_RWCMD is converted to a read or a write */ {0, DIOCTL_RWCMD, sizeof (struct dadkio_rwcmd), NULL}, /* mhd(7I) non-shared multihost disks ioctls */ {0, MHIOCTKOWN, 0, vdc_null_copy_func}, {0, MHIOCRELEASE, 0, vdc_null_copy_func}, {0, MHIOCSTATUS, 0, vdc_null_copy_func}, {0, MHIOCQRESERVE, 0, vdc_null_copy_func}, /* mhd(7I) shared multihost disks ioctls */ {0, MHIOCGRP_INKEYS, 0, vdc_null_copy_func}, {0, MHIOCGRP_INRESV, 0, vdc_null_copy_func}, {0, MHIOCGRP_REGISTER, 0, vdc_null_copy_func}, {0, MHIOCGRP_RESERVE, 0, vdc_null_copy_func}, {0, MHIOCGRP_PREEMPTANDABORT, 0, vdc_null_copy_func}, {0, MHIOCGRP_REGISTERANDIGNOREKEY, 0, vdc_null_copy_func}, /* mhd(7I) failfast ioctl */ {0, MHIOCENFAILFAST, 0, vdc_null_copy_func}, /* * These particular ioctls are not sent to the server - vdc fakes up * the necessary info. */ {0, DKIOCINFO, sizeof (struct dk_cinfo), vdc_null_copy_func}, {0, DKIOCGMEDIAINFO, sizeof (struct dk_minfo), vdc_null_copy_func}, {0, USCSICMD, sizeof (struct uscsi_cmd), vdc_null_copy_func}, {0, DKIOCGAPART, 0, vdc_null_copy_func }, {0, DKIOCREMOVABLE, 0, vdc_null_copy_func}, {0, CDROMREADOFFSET, 0, vdc_null_copy_func} }; /* * The signature of vd_process_ioctl() has changed to include the return value * pointer. However we don't want to change vd_efi_* functions now so we add * this wrapper function so that we can use it with vdc_efi_init(). * * vd_efi_* functions need some changes to fix 6528974 and so we will eventually * remove this function when fixing that bug. */ static int vd_process_efi_ioctl(dev_t dev, int cmd, caddr_t arg, int mode) { int rval; return (vd_process_ioctl(dev, cmd, arg, mode, &rval)); } /* * Function: * vd_process_ioctl() * * Description: * This routine processes disk specific ioctl calls * * Arguments: * dev - the device number * cmd - the operation [dkio(7I)] to be processed * arg - pointer to user provided structure * (contains data to be set or reference parameter for get) * mode - bit flag, indicating open settings, 32/64 bit type, etc * rvalp - pointer to return value for calling process. * * Return Code: * 0 * EFAULT * ENXIO * EIO * ENOTSUP */ static int vd_process_ioctl(dev_t dev, int cmd, caddr_t arg, int mode, int *rvalp) { int instance = VDCUNIT(dev); vdc_t *vdc = NULL; int rv = -1; int idx = 0; /* index into dk_ioctl[] */ size_t len = 0; /* #bytes to send to vds */ size_t alloc_len = 0; /* #bytes to allocate mem for */ caddr_t mem_p = NULL; size_t nioctls = (sizeof (dk_ioctl)) / (sizeof (dk_ioctl[0])); vdc_dk_ioctl_t *iop; vdc = ddi_get_soft_state(vdc_state, instance); if (vdc == NULL) { cmn_err(CE_NOTE, "![%d] Could not get soft state structure", instance); return (ENXIO); } DMSG(vdc, 0, "[%d] Processing ioctl(%x) for dev %lx : model %x\n", instance, cmd, dev, ddi_model_convert_from(mode & FMODELS)); if (rvalp != NULL) { /* the return value of the ioctl is 0 by default */ *rvalp = 0; } /* * Validate the ioctl operation to be performed. * * If we have looped through the array without finding a match then we * don't support this ioctl. */ for (idx = 0; idx < nioctls; idx++) { if (cmd == dk_ioctl[idx].cmd) break; } if (idx >= nioctls) { DMSG(vdc, 0, "[%d] Unsupported ioctl (0x%x)\n", vdc->instance, cmd); return (ENOTSUP); } iop = &(dk_ioctl[idx]); if (cmd == DKIOCGETEFI || cmd == DKIOCSETEFI) { /* size is not fixed for EFI ioctls, it depends on ioctl arg */ dk_efi_t dk_efi; rv = ddi_copyin(arg, &dk_efi, sizeof (dk_efi_t), mode); if (rv != 0) return (EFAULT); len = sizeof (vd_efi_t) - 1 + dk_efi.dki_length; } else { len = iop->nbytes; } /* check if the ioctl is applicable */ switch (cmd) { case CDROMREADOFFSET: case DKIOCREMOVABLE: return (ENOTTY); case USCSICMD: case MHIOCTKOWN: case MHIOCSTATUS: case MHIOCQRESERVE: case MHIOCRELEASE: case MHIOCGRP_INKEYS: case MHIOCGRP_INRESV: case MHIOCGRP_REGISTER: case MHIOCGRP_RESERVE: case MHIOCGRP_PREEMPTANDABORT: case MHIOCGRP_REGISTERANDIGNOREKEY: case MHIOCENFAILFAST: if (vdc->cinfo == NULL) return (ENXIO); if (vdc->cinfo->dki_ctype != DKC_SCSI_CCS) return (ENOTTY); break; case DIOCTL_RWCMD: if (vdc->cinfo == NULL) return (ENXIO); if (vdc->cinfo->dki_ctype != DKC_DIRECT) return (ENOTTY); break; case DKIOCINFO: if (vdc->cinfo == NULL) return (ENXIO); break; case DKIOCGMEDIAINFO: if (vdc->minfo == NULL) return (ENXIO); if (vdc_check_capacity(vdc) != 0) /* disk capacity is not available */ return (EIO); break; } /* * Deal with ioctls which require a processing different than * converting ioctl arguments and sending a corresponding * VD operation. */ switch (cmd) { case USCSICMD: { return (vdc_uscsi_cmd(vdc, arg, mode)); } case MHIOCTKOWN: { mutex_enter(&vdc->ownership_lock); /* * We have to set VDC_OWNERSHIP_WANTED now so that the ownership * can be flagged with VDC_OWNERSHIP_RESET if the LDC is reset * while we are processing the ioctl. */ vdc_ownership_update(vdc, VDC_OWNERSHIP_WANTED); rv = vdc_access_set(vdc, VD_ACCESS_SET_EXCLUSIVE | VD_ACCESS_SET_PREEMPT | VD_ACCESS_SET_PRESERVE, mode); if (rv == 0) { vdc_ownership_update(vdc, VDC_OWNERSHIP_WANTED | VDC_OWNERSHIP_GRANTED); } else { vdc_ownership_update(vdc, VDC_OWNERSHIP_NONE); } mutex_exit(&vdc->ownership_lock); return (rv); } case MHIOCRELEASE: { mutex_enter(&vdc->ownership_lock); rv = vdc_access_set(vdc, VD_ACCESS_SET_CLEAR, mode); if (rv == 0) { vdc_ownership_update(vdc, VDC_OWNERSHIP_NONE); } mutex_exit(&vdc->ownership_lock); return (rv); } case MHIOCSTATUS: { uint64_t status; rv = vdc_access_get(vdc, &status, mode); if (rv == 0 && rvalp != NULL) *rvalp = (status & VD_ACCESS_ALLOWED)? 0 : 1; return (rv); } case MHIOCQRESERVE: { rv = vdc_access_set(vdc, VD_ACCESS_SET_EXCLUSIVE, mode); return (rv); } case MHIOCGRP_INKEYS: { return (vdc_mhd_inkeys(vdc, arg, mode)); } case MHIOCGRP_INRESV: { return (vdc_mhd_inresv(vdc, arg, mode)); } case MHIOCGRP_REGISTER: { return (vdc_mhd_register(vdc, arg, mode)); } case MHIOCGRP_RESERVE: { return (vdc_mhd_reserve(vdc, arg, mode)); } case MHIOCGRP_PREEMPTANDABORT: { return (vdc_mhd_preemptabort(vdc, arg, mode)); } case MHIOCGRP_REGISTERANDIGNOREKEY: { return (vdc_mhd_registerignore(vdc, arg, mode)); } case MHIOCENFAILFAST: { rv = vdc_failfast(vdc, arg, mode); return (rv); } case DIOCTL_RWCMD: { return (vdc_dioctl_rwcmd(dev, arg, mode)); } case DKIOCGAPART: { return (vdc_dkio_get_partition(vdc, arg, mode)); } case DKIOCINFO: { struct dk_cinfo cinfo; bcopy(vdc->cinfo, &cinfo, sizeof (struct dk_cinfo)); cinfo.dki_partition = VDCPART(dev); rv = ddi_copyout(&cinfo, (void *)arg, sizeof (struct dk_cinfo), mode); if (rv != 0) return (EFAULT); return (0); } case DKIOCGMEDIAINFO: { ASSERT(vdc->vdisk_size != 0); if (vdc->minfo->dki_capacity == 0) vdc->minfo->dki_capacity = vdc->vdisk_size; rv = ddi_copyout(vdc->minfo, (void *)arg, sizeof (struct dk_minfo), mode); if (rv != 0) return (EFAULT); return (0); } case DKIOCFLUSHWRITECACHE: { struct dk_callback *dkc = (struct dk_callback *)(uintptr_t)arg; vdc_dk_arg_t *dkarg = NULL; DMSG(vdc, 1, "[%d] Flush W$: mode %x\n", instance, mode); /* * If arg is NULL, then there is no callback function * registered and the call operates synchronously; we * break and continue with the rest of the function and * wait for vds to return (i.e. after the request to * vds returns successfully, all writes completed prior * to the ioctl will have been flushed from the disk * write cache to persistent media. * * If a callback function is registered, we dispatch * the request on a task queue and return immediately. * The callback will deal with informing the calling * thread that the flush request is completed. */ if (dkc == NULL) break; /* * the asynchronous callback is only supported if * invoked from within the kernel */ if ((mode & FKIOCTL) == 0) return (ENOTSUP); dkarg = kmem_zalloc(sizeof (vdc_dk_arg_t), KM_SLEEP); dkarg->mode = mode; dkarg->dev = dev; bcopy(dkc, &dkarg->dkc, sizeof (*dkc)); mutex_enter(&vdc->lock); vdc->dkio_flush_pending++; dkarg->vdc = vdc; mutex_exit(&vdc->lock); /* put the request on a task queue */ rv = taskq_dispatch(system_taskq, vdc_dkio_flush_cb, (void *)dkarg, DDI_SLEEP); if (rv == NULL) { /* clean up if dispatch fails */ mutex_enter(&vdc->lock); vdc->dkio_flush_pending--; mutex_exit(&vdc->lock); kmem_free(dkarg, sizeof (vdc_dk_arg_t)); } return (rv == NULL ? ENOMEM : 0); } } /* catch programming error in vdc - should be a VD_OP_XXX ioctl */ ASSERT(iop->op != 0); /* check if the vDisk server handles the operation for this vDisk */ if (VD_OP_SUPPORTED(vdc->operations, iop->op) == B_FALSE) { DMSG(vdc, 0, "[%d] Unsupported VD_OP operation (0x%x)\n", vdc->instance, iop->op); return (ENOTSUP); } /* LDC requires that the memory being mapped is 8-byte aligned */ alloc_len = P2ROUNDUP(len, sizeof (uint64_t)); DMSG(vdc, 1, "[%d] struct size %ld alloc %ld\n", instance, len, alloc_len); if (alloc_len > 0) mem_p = kmem_zalloc(alloc_len, KM_SLEEP); /* * Call the conversion function for this ioctl which, if necessary, * converts from the Solaris format to the format ARC'ed * as part of the vDisk protocol (FWARC 2006/195) */ ASSERT(iop->convert != NULL); rv = (iop->convert)(vdc, arg, mem_p, mode, VD_COPYIN); if (rv != 0) { DMSG(vdc, 0, "[%d] convert func returned %d for ioctl 0x%x\n", instance, rv, cmd); if (mem_p != NULL) kmem_free(mem_p, alloc_len); return (rv); } /* * send request to vds to service the ioctl. */ rv = vdc_do_sync_op(vdc, iop->op, mem_p, alloc_len, VDCPART(dev), 0, CB_SYNC, (void *)(uint64_t)mode, VIO_both_dir, B_TRUE); if (rv != 0) { /* * This is not necessarily an error. The ioctl could * be returning a value such as ENOTTY to indicate * that the ioctl is not applicable. */ DMSG(vdc, 0, "[%d] vds returned %d for ioctl 0x%x\n", instance, rv, cmd); if (mem_p != NULL) kmem_free(mem_p, alloc_len); return (rv); } /* * Call the conversion function (if it exists) for this ioctl * which converts from the format ARC'ed as part of the vDisk * protocol (FWARC 2006/195) back to a format understood by * the rest of Solaris. */ rv = (iop->convert)(vdc, mem_p, arg, mode, VD_COPYOUT); if (rv != 0) { DMSG(vdc, 0, "[%d] convert func returned %d for ioctl 0x%x\n", instance, rv, cmd); if (mem_p != NULL) kmem_free(mem_p, alloc_len); return (rv); } if (mem_p != NULL) kmem_free(mem_p, alloc_len); return (rv); } /* * Function: * * Description: * This is an empty conversion function used by ioctl calls which * do not need to convert the data being passed in/out to userland */ static int vdc_null_copy_func(vdc_t *vdc, void *from, void *to, int mode, int dir) { _NOTE(ARGUNUSED(vdc)) _NOTE(ARGUNUSED(from)) _NOTE(ARGUNUSED(to)) _NOTE(ARGUNUSED(mode)) _NOTE(ARGUNUSED(dir)) return (0); } static int vdc_get_wce_convert(vdc_t *vdc, void *from, void *to, int mode, int dir) { _NOTE(ARGUNUSED(vdc)) if (dir == VD_COPYIN) return (0); /* nothing to do */ if (ddi_copyout(from, to, sizeof (int), mode) != 0) return (EFAULT); return (0); } static int vdc_set_wce_convert(vdc_t *vdc, void *from, void *to, int mode, int dir) { _NOTE(ARGUNUSED(vdc)) if (dir == VD_COPYOUT) return (0); /* nothing to do */ if (ddi_copyin(from, to, sizeof (int), mode) != 0) return (EFAULT); return (0); } /* * Function: * vdc_get_vtoc_convert() * * Description: * This routine performs the necessary convertions from the DKIOCGVTOC * Solaris structure to the format defined in FWARC 2006/195. * * In the struct vtoc definition, the timestamp field is marked as not * supported so it is not part of vDisk protocol (FWARC 2006/195). * However SVM uses that field to check it can write into the VTOC, * so we fake up the info of that field. * * Arguments: * vdc - the vDisk client * from - the buffer containing the data to be copied from * to - the buffer to be copied to * mode - flags passed to ioctl() call * dir - the "direction" of the copy - VD_COPYIN or VD_COPYOUT * * Return Code: * 0 - Success * ENXIO - incorrect buffer passed in. * EFAULT - ddi_copyout routine encountered an error. */ static int vdc_get_vtoc_convert(vdc_t *vdc, void *from, void *to, int mode, int dir) { int i; void *tmp_mem = NULL; void *tmp_memp; struct vtoc vt; struct vtoc32 vt32; int copy_len = 0; int rv = 0; if (dir != VD_COPYOUT) return (0); /* nothing to do */ if ((from == NULL) || (to == NULL)) return (ENXIO); if (ddi_model_convert_from(mode & FMODELS) == DDI_MODEL_ILP32) copy_len = sizeof (struct vtoc32); else copy_len = sizeof (struct vtoc); tmp_mem = kmem_alloc(copy_len, KM_SLEEP); VD_VTOC2VTOC((vd_vtoc_t *)from, &vt); /* fake the VTOC timestamp field */ for (i = 0; i < V_NUMPAR; i++) { vt.timestamp[i] = vdc->vtoc->timestamp[i]; } if (ddi_model_convert_from(mode & FMODELS) == DDI_MODEL_ILP32) { /* LINTED E_ASSIGN_NARROW_CONV */ vtoctovtoc32(vt, vt32); tmp_memp = &vt32; } else { tmp_memp = &vt; } rv = ddi_copyout(tmp_memp, to, copy_len, mode); if (rv != 0) rv = EFAULT; kmem_free(tmp_mem, copy_len); return (rv); } /* * Function: * vdc_set_vtoc_convert() * * Description: * This routine performs the necessary convertions from the DKIOCSVTOC * Solaris structure to the format defined in FWARC 2006/195. * * Arguments: * vdc - the vDisk client * from - Buffer with data * to - Buffer where data is to be copied to * mode - flags passed to ioctl * dir - direction of copy (in or out) * * Return Code: * 0 - Success * ENXIO - Invalid buffer passed in * EFAULT - ddi_copyin of data failed */ static int vdc_set_vtoc_convert(vdc_t *vdc, void *from, void *to, int mode, int dir) { _NOTE(ARGUNUSED(vdc)) void *tmp_mem = NULL, *uvtoc; struct vtoc vt; struct vtoc *vtp = &vt; vd_vtoc_t vtvd; int copy_len = 0; int i, rv = 0; if ((from == NULL) || (to == NULL)) return (ENXIO); if (dir == VD_COPYIN) uvtoc = from; else uvtoc = to; if (ddi_model_convert_from(mode & FMODELS) == DDI_MODEL_ILP32) copy_len = sizeof (struct vtoc32); else copy_len = sizeof (struct vtoc); tmp_mem = kmem_alloc(copy_len, KM_SLEEP); rv = ddi_copyin(uvtoc, tmp_mem, copy_len, mode); if (rv != 0) { kmem_free(tmp_mem, copy_len); return (EFAULT); } if (ddi_model_convert_from(mode & FMODELS) == DDI_MODEL_ILP32) { vtoc32tovtoc((*(struct vtoc32 *)tmp_mem), vt); } else { vtp = tmp_mem; } if (dir == VD_COPYOUT) { /* * The disk label may have changed. Revalidate the disk * geometry. This will also update the device nodes and * properties. */ vdc_validate(vdc); /* * We also need to keep track of the timestamp fields. */ for (i = 0; i < V_NUMPAR; i++) { vdc->vtoc->timestamp[i] = vtp->timestamp[i]; } return (0); } VTOC2VD_VTOC(vtp, &vtvd); bcopy(&vtvd, to, sizeof (vd_vtoc_t)); kmem_free(tmp_mem, copy_len); return (0); } /* * Function: * vdc_get_geom_convert() * * Description: * This routine performs the necessary convertions from the DKIOCGGEOM, * DKIOCG_PHYSGEOM and DKIOG_VIRTGEOM Solaris structures to the format * defined in FWARC 2006/195 * * Arguments: * vdc - the vDisk client * from - Buffer with data * to - Buffer where data is to be copied to * mode - flags passed to ioctl * dir - direction of copy (in or out) * * Return Code: * 0 - Success * ENXIO - Invalid buffer passed in * EFAULT - ddi_copyout of data failed */ static int vdc_get_geom_convert(vdc_t *vdc, void *from, void *to, int mode, int dir) { _NOTE(ARGUNUSED(vdc)) struct dk_geom geom; int copy_len = sizeof (struct dk_geom); int rv = 0; if (dir != VD_COPYOUT) return (0); /* nothing to do */ if ((from == NULL) || (to == NULL)) return (ENXIO); VD_GEOM2DK_GEOM((vd_geom_t *)from, &geom); rv = ddi_copyout(&geom, to, copy_len, mode); if (rv != 0) rv = EFAULT; return (rv); } /* * Function: * vdc_set_geom_convert() * * Description: * This routine performs the necessary convertions from the DKIOCSGEOM * Solaris structure to the format defined in FWARC 2006/195. * * Arguments: * vdc - the vDisk client * from - Buffer with data * to - Buffer where data is to be copied to * mode - flags passed to ioctl * dir - direction of copy (in or out) * * Return Code: * 0 - Success * ENXIO - Invalid buffer passed in * EFAULT - ddi_copyin of data failed */ static int vdc_set_geom_convert(vdc_t *vdc, void *from, void *to, int mode, int dir) { _NOTE(ARGUNUSED(vdc)) vd_geom_t vdgeom; void *tmp_mem = NULL; int copy_len = sizeof (struct dk_geom); int rv = 0; if (dir != VD_COPYIN) return (0); /* nothing to do */ if ((from == NULL) || (to == NULL)) return (ENXIO); tmp_mem = kmem_alloc(copy_len, KM_SLEEP); rv = ddi_copyin(from, tmp_mem, copy_len, mode); if (rv != 0) { kmem_free(tmp_mem, copy_len); return (EFAULT); } DK_GEOM2VD_GEOM((struct dk_geom *)tmp_mem, &vdgeom); bcopy(&vdgeom, to, sizeof (vdgeom)); kmem_free(tmp_mem, copy_len); return (0); } static int vdc_get_efi_convert(vdc_t *vdc, void *from, void *to, int mode, int dir) { _NOTE(ARGUNUSED(vdc)) vd_efi_t *vd_efi; dk_efi_t dk_efi; int rv = 0; void *uaddr; if ((from == NULL) || (to == NULL)) return (ENXIO); if (dir == VD_COPYIN) { vd_efi = (vd_efi_t *)to; rv = ddi_copyin(from, &dk_efi, sizeof (dk_efi_t), mode); if (rv != 0) return (EFAULT); vd_efi->lba = dk_efi.dki_lba; vd_efi->length = dk_efi.dki_length; bzero(vd_efi->data, vd_efi->length); } else { rv = ddi_copyin(to, &dk_efi, sizeof (dk_efi_t), mode); if (rv != 0) return (EFAULT); uaddr = dk_efi.dki_data; dk_efi.dki_data = kmem_alloc(dk_efi.dki_length, KM_SLEEP); VD_EFI2DK_EFI((vd_efi_t *)from, &dk_efi); rv = ddi_copyout(dk_efi.dki_data, uaddr, dk_efi.dki_length, mode); if (rv != 0) return (EFAULT); kmem_free(dk_efi.dki_data, dk_efi.dki_length); } return (0); } static int vdc_set_efi_convert(vdc_t *vdc, void *from, void *to, int mode, int dir) { _NOTE(ARGUNUSED(vdc)) dk_efi_t dk_efi; void *uaddr; if (dir == VD_COPYOUT) { /* * The disk label may have changed. Revalidate the disk * geometry. This will also update the device nodes and * properties. */ vdc_validate(vdc); return (0); } if ((from == NULL) || (to == NULL)) return (ENXIO); if (ddi_copyin(from, &dk_efi, sizeof (dk_efi_t), mode) != 0) return (EFAULT); uaddr = dk_efi.dki_data; dk_efi.dki_data = kmem_alloc(dk_efi.dki_length, KM_SLEEP); if (ddi_copyin(uaddr, dk_efi.dki_data, dk_efi.dki_length, mode) != 0) return (EFAULT); DK_EFI2VD_EFI(&dk_efi, (vd_efi_t *)to); kmem_free(dk_efi.dki_data, dk_efi.dki_length); return (0); } /* -------------------------------------------------------------------------- */ /* * Function: * vdc_create_fake_geometry() * * Description: * This routine fakes up the disk info needed for some DKIO ioctls such * as DKIOCINFO and DKIOCGMEDIAINFO [just like lofi(7D) and ramdisk(7D) do] * * Note: This function must not be called until the vDisk attributes have * been exchanged as part of the handshake with the vDisk server. * * Arguments: * vdc - soft state pointer for this instance of the device driver. * * Return Code: * none. */ static void vdc_create_fake_geometry(vdc_t *vdc) { ASSERT(vdc != NULL); ASSERT(vdc->max_xfer_sz != 0); /* * DKIOCINFO support */ if (vdc->cinfo == NULL) vdc->cinfo = kmem_zalloc(sizeof (struct dk_cinfo), KM_SLEEP); (void) strcpy(vdc->cinfo->dki_cname, VDC_DRIVER_NAME); (void) strcpy(vdc->cinfo->dki_dname, VDC_DRIVER_NAME); /* max_xfer_sz is #blocks so we don't need to divide by DEV_BSIZE */ vdc->cinfo->dki_maxtransfer = vdc->max_xfer_sz; /* * We set the controller type to DKC_SCSI_CCS only if the VD_OP_SCSICMD * operation is supported, otherwise the controller type is DKC_DIRECT. * Version 1.0 does not support the VD_OP_SCSICMD operation, so the * controller type is always DKC_DIRECT in that case. * * If the virtual disk is backed by a physical CD/DVD device or * an ISO image, modify the controller type to indicate this */ switch (vdc->vdisk_media) { case VD_MEDIA_CD: case VD_MEDIA_DVD: vdc->cinfo->dki_ctype = DKC_CDROM; break; case VD_MEDIA_FIXED: if (VD_OP_SUPPORTED(vdc->operations, VD_OP_SCSICMD)) vdc->cinfo->dki_ctype = DKC_SCSI_CCS; else vdc->cinfo->dki_ctype = DKC_DIRECT; break; default: /* in the case of v1.0 we default to a fixed disk */ vdc->cinfo->dki_ctype = DKC_DIRECT; break; } vdc->cinfo->dki_flags = DKI_FMTVOL; vdc->cinfo->dki_cnum = 0; vdc->cinfo->dki_addr = 0; vdc->cinfo->dki_space = 0; vdc->cinfo->dki_prio = 0; vdc->cinfo->dki_vec = 0; vdc->cinfo->dki_unit = vdc->instance; vdc->cinfo->dki_slave = 0; /* * The partition number will be created on the fly depending on the * actual slice (i.e. minor node) that is used to request the data. */ vdc->cinfo->dki_partition = 0; /* * DKIOCGMEDIAINFO support */ if (vdc->minfo == NULL) vdc->minfo = kmem_zalloc(sizeof (struct dk_minfo), KM_SLEEP); if (vio_ver_is_supported(vdc->ver, 1, 1)) { vdc->minfo->dki_media_type = VD_MEDIATYPE2DK_MEDIATYPE(vdc->vdisk_media); } else { vdc->minfo->dki_media_type = DK_FIXED_DISK; } vdc->minfo->dki_capacity = vdc->vdisk_size; vdc->minfo->dki_lbsize = vdc->block_size; } static ushort_t vdc_lbl2cksum(struct dk_label *label) { int count; ushort_t sum, *sp; count = (sizeof (struct dk_label)) / (sizeof (short)) - 1; sp = (ushort_t *)label; sum = 0; while (count--) { sum ^= *sp++; } return (sum); } /* * Function: * vdc_validate_geometry * * Description: * This routine discovers the label and geometry of the disk. It stores * the disk label and related information in the vdc structure. If it * fails to validate the geometry or to discover the disk label then * the label is marked as unknown (VD_DISK_LABEL_UNK). * * Arguments: * vdc - soft state pointer for this instance of the device driver. * * Return Code: * 0 - success. * EINVAL - unknown disk label. * ENOTSUP - geometry not applicable (EFI label). * EIO - error accessing the disk. */ static int vdc_validate_geometry(vdc_t *vdc) { buf_t *buf; /* BREAD requests need to be in a buf_t structure */ dev_t dev; int rv, rval; struct dk_label label; struct dk_geom geom; struct vtoc vtoc; ASSERT(vdc != NULL); ASSERT(vdc->vtoc != NULL && vdc->geom != NULL); ASSERT(MUTEX_HELD(&vdc->lock)); mutex_exit(&vdc->lock); dev = makedevice(ddi_driver_major(vdc->dip), VD_MAKE_DEV(vdc->instance, 0)); rv = vd_process_ioctl(dev, DKIOCGGEOM, (caddr_t)&geom, FKIOCTL, &rval); if (rv == 0) rv = vd_process_ioctl(dev, DKIOCGVTOC, (caddr_t)&vtoc, FKIOCTL, &rval); if (rv == ENOTSUP) { /* * If the device does not support VTOC then we try * to read an EFI label. */ struct dk_gpt *efi; size_t efi_len; rv = vdc_efi_alloc_and_read(dev, &efi, &efi_len); if (rv) { DMSG(vdc, 0, "[%d] Failed to get EFI (err=%d)", vdc->instance, rv); mutex_enter(&vdc->lock); vdc_store_label_unk(vdc); return (EIO); } mutex_enter(&vdc->lock); vdc_store_label_efi(vdc, efi); vd_efi_free(efi, efi_len); return (ENOTSUP); } if (rv != 0) { DMSG(vdc, 0, "[%d] Failed to get VTOC (err=%d)", vdc->instance, rv); mutex_enter(&vdc->lock); vdc_store_label_unk(vdc); if (rv != EINVAL) rv = EIO; return (rv); } /* check that geometry and vtoc are valid */ if (geom.dkg_nhead == 0 || geom.dkg_nsect == 0 || vtoc.v_sanity != VTOC_SANE) { mutex_enter(&vdc->lock); vdc_store_label_unk(vdc); return (EINVAL); } /* * We have a disk and a valid VTOC. However this does not mean * that the disk currently have a VTOC label. The returned VTOC may * be a default VTOC to be used for configuring the disk (this is * what is done for disk image). So we read the label from the * beginning of the disk to ensure we really have a VTOC label. * * FUTURE: This could be the default way for reading the VTOC * from the disk as opposed to sending the VD_OP_GET_VTOC * to the server. This will be the default if vdc is implemented * ontop of cmlb. */ /* * Single slice disk does not support read using an absolute disk * offset so we just rely on the DKIOCGVTOC ioctl in that case. */ if (vdc->vdisk_type == VD_DISK_TYPE_SLICE) { mutex_enter(&vdc->lock); if (vtoc.v_nparts != 1) { vdc_store_label_unk(vdc); return (EINVAL); } vdc_store_label_vtoc(vdc, &geom, &vtoc); return (0); } if (vtoc.v_nparts != V_NUMPAR) { mutex_enter(&vdc->lock); vdc_store_label_unk(vdc); return (EINVAL); } /* * Read disk label from start of disk */ buf = kmem_alloc(sizeof (buf_t), KM_SLEEP); bioinit(buf); buf->b_un.b_addr = (caddr_t)&label; buf->b_bcount = DK_LABEL_SIZE; buf->b_flags = B_BUSY | B_READ; buf->b_dev = cmpdev(dev); rv = vdc_send_request(vdc, VD_OP_BREAD, (caddr_t)&label, DK_LABEL_SIZE, VD_SLICE_NONE, 0, CB_STRATEGY, buf, VIO_read_dir); if (rv) { DMSG(vdc, 1, "[%d] Failed to read disk block 0\n", vdc->instance); } else { rv = biowait(buf); biofini(buf); } kmem_free(buf, sizeof (buf_t)); if (rv != 0 || label.dkl_magic != DKL_MAGIC || label.dkl_cksum != vdc_lbl2cksum(&label)) { DMSG(vdc, 1, "[%d] Got VTOC with invalid label\n", vdc->instance); mutex_enter(&vdc->lock); vdc_store_label_unk(vdc); return (EINVAL); } mutex_enter(&vdc->lock); vdc_store_label_vtoc(vdc, &geom, &vtoc); return (0); } /* * Function: * vdc_validate * * Description: * This routine discovers the label of the disk and create the * appropriate device nodes if the label has changed. * * Arguments: * vdc - soft state pointer for this instance of the device driver. * * Return Code: * none. */ static void vdc_validate(vdc_t *vdc) { vd_disk_label_t old_label; struct vtoc old_vtoc; int rv; ASSERT(!MUTEX_HELD(&vdc->lock)); mutex_enter(&vdc->lock); /* save the current label and vtoc */ old_label = vdc->vdisk_label; bcopy(vdc->vtoc, &old_vtoc, sizeof (struct vtoc)); /* check the geometry */ (void) vdc_validate_geometry(vdc); /* if the disk label has changed, update device nodes */ if (vdc->vdisk_label != old_label) { if (vdc->vdisk_label == VD_DISK_LABEL_EFI) rv = vdc_create_device_nodes_efi(vdc); else rv = vdc_create_device_nodes_vtoc(vdc); if (rv != 0) { DMSG(vdc, 0, "![%d] Failed to update device nodes", vdc->instance); } } /* if the vtoc has changed, update device nodes properties */ if (bcmp(vdc->vtoc, &old_vtoc, sizeof (struct vtoc)) != 0) { if (vdc_create_device_nodes_props(vdc) != 0) { DMSG(vdc, 0, "![%d] Failed to update device nodes" " properties", vdc->instance); } } mutex_exit(&vdc->lock); } static void vdc_validate_task(void *arg) { vdc_t *vdc = (vdc_t *)arg; vdc_validate(vdc); mutex_enter(&vdc->lock); ASSERT(vdc->validate_pending > 0); vdc->validate_pending--; mutex_exit(&vdc->lock); } /* * Function: * vdc_setup_devid() * * Description: * This routine discovers the devid of a vDisk. It requests the devid of * the underlying device from the vDisk server, builds an encapsulated * devid based on the retrieved devid and registers that new devid to * the vDisk. * * Arguments: * vdc - soft state pointer for this instance of the device driver. * * Return Code: * 0 - A devid was succesfully registered for the vDisk */ static int vdc_setup_devid(vdc_t *vdc) { int rv; vd_devid_t *vd_devid; size_t bufsize, bufid_len; /* * At first sight, we don't know the size of the devid that the * server will return but this size will be encoded into the * reply. So we do a first request using a default size then we * check if this size was large enough. If not then we do a second * request with the correct size returned by the server. Note that * ldc requires size to be 8-byte aligned. */ bufsize = P2ROUNDUP(VD_DEVID_SIZE(VD_DEVID_DEFAULT_LEN), sizeof (uint64_t)); vd_devid = kmem_zalloc(bufsize, KM_SLEEP); bufid_len = bufsize - sizeof (vd_efi_t) - 1; rv = vdc_do_sync_op(vdc, VD_OP_GET_DEVID, (caddr_t)vd_devid, bufsize, 0, 0, CB_SYNC, 0, VIO_both_dir, B_TRUE); DMSG(vdc, 2, "sync_op returned %d\n", rv); if (rv) { kmem_free(vd_devid, bufsize); return (rv); } if (vd_devid->length > bufid_len) { /* * The returned devid is larger than the buffer used. Try again * with a buffer with the right size. */ kmem_free(vd_devid, bufsize); bufsize = P2ROUNDUP(VD_DEVID_SIZE(vd_devid->length), sizeof (uint64_t)); vd_devid = kmem_zalloc(bufsize, KM_SLEEP); bufid_len = bufsize - sizeof (vd_efi_t) - 1; rv = vdc_do_sync_op(vdc, VD_OP_GET_DEVID, (caddr_t)vd_devid, bufsize, 0, 0, CB_SYNC, 0, VIO_both_dir, B_TRUE); if (rv) { kmem_free(vd_devid, bufsize); return (rv); } } /* * The virtual disk should have the same device id as the one associated * with the physical disk it is mapped on, otherwise sharing a disk * between a LDom and a non-LDom may not work (for example for a shared * SVM disk set). * * The DDI framework does not allow creating a device id with any * type so we first create a device id of type DEVID_ENCAP and then * we restore the orignal type of the physical device. */ DMSG(vdc, 2, ": devid length = %d\n", vd_devid->length); /* build an encapsulated devid based on the returned devid */ if (ddi_devid_init(vdc->dip, DEVID_ENCAP, vd_devid->length, vd_devid->id, &vdc->devid) != DDI_SUCCESS) { DMSG(vdc, 1, "[%d] Fail to created devid\n", vdc->instance); kmem_free(vd_devid, bufsize); return (1); } DEVID_FORMTYPE((impl_devid_t *)vdc->devid, vd_devid->type); ASSERT(ddi_devid_valid(vdc->devid) == DDI_SUCCESS); kmem_free(vd_devid, bufsize); if (ddi_devid_register(vdc->dip, vdc->devid) != DDI_SUCCESS) { DMSG(vdc, 1, "[%d] Fail to register devid\n", vdc->instance); return (1); } return (0); } static void vdc_store_label_efi(vdc_t *vdc, struct dk_gpt *efi) { struct vtoc *vtoc = vdc->vtoc; ASSERT(MUTEX_HELD(&vdc->lock)); vdc->vdisk_label = VD_DISK_LABEL_EFI; bzero(vdc->geom, sizeof (struct dk_geom)); vd_efi_to_vtoc(efi, vtoc); if (vdc->vdisk_type == VD_DISK_TYPE_SLICE) { /* * vd_efi_to_vtoc() will store information about the EFI Sun * reserved partition (representing the entire disk) into * partition 7. However single-slice device will only have * that single partition and the vdc driver expects to find * information about that partition in slice 0. So we need * to copy information from slice 7 to slice 0. */ vtoc->v_part[0].p_tag = vtoc->v_part[VD_EFI_WD_SLICE].p_tag; vtoc->v_part[0].p_flag = vtoc->v_part[VD_EFI_WD_SLICE].p_flag; vtoc->v_part[0].p_start = vtoc->v_part[VD_EFI_WD_SLICE].p_start; vtoc->v_part[0].p_size = vtoc->v_part[VD_EFI_WD_SLICE].p_size; } } static void vdc_store_label_vtoc(vdc_t *vdc, struct dk_geom *geom, struct vtoc *vtoc) { ASSERT(MUTEX_HELD(&vdc->lock)); vdc->vdisk_label = VD_DISK_LABEL_VTOC; bcopy(vtoc, vdc->vtoc, sizeof (struct vtoc)); bcopy(geom, vdc->geom, sizeof (struct dk_geom)); } static void vdc_store_label_unk(vdc_t *vdc) { ASSERT(MUTEX_HELD(&vdc->lock)); vdc->vdisk_label = VD_DISK_LABEL_UNK; bzero(vdc->vtoc, sizeof (struct vtoc)); bzero(vdc->geom, sizeof (struct dk_geom)); }