Current Path : /sys/amd64/compile/hs32/modules/usr/src/sys/modules/nge/@/cam/ctl/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //sys/amd64/compile/hs32/modules/usr/src/sys/modules/nge/@/cam/ctl/ctl.c |
/*- * Copyright (c) 2003-2009 Silicon Graphics International Corp. * Copyright (c) 2012 The FreeBSD Foundation * All rights reserved. * * Portions of this software were developed by Edward Tomasz Napierala * under sponsorship from the FreeBSD Foundation. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions, and the following disclaimer, * without modification. * 2. Redistributions in binary form must reproduce at minimum a disclaimer * substantially similar to the "NO WARRANTY" disclaimer below * ("Disclaimer") and any redistribution must be conditioned upon * including a substantially similar Disclaimer requirement for further * binary redistribution. * * NO WARRANTY * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTIBILITY AND FITNESS FOR * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT * HOLDERS OR CONTRIBUTORS BE LIABLE FOR SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING * IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGES. * * $Id: //depot/users/kenm/FreeBSD-test2/sys/cam/ctl/ctl.c#8 $ */ /* * CAM Target Layer, a SCSI device emulation subsystem. * * Author: Ken Merry <ken@FreeBSD.org> */ #define _CTL_C #include <sys/cdefs.h> __FBSDID("$FreeBSD: release/9.1.0/sys/cam/ctl/ctl.c 237941 2012-07-02 02:36:05Z ken $"); #include <sys/param.h> #include <sys/systm.h> #include <sys/kernel.h> #include <sys/types.h> #include <sys/kthread.h> #include <sys/bio.h> #include <sys/fcntl.h> #include <sys/lock.h> #include <sys/mutex.h> #include <sys/condvar.h> #include <sys/malloc.h> #include <sys/conf.h> #include <sys/ioccom.h> #include <sys/queue.h> #include <sys/sbuf.h> #include <sys/endian.h> #include <sys/sysctl.h> #include <cam/cam.h> #include <cam/scsi/scsi_all.h> #include <cam/scsi/scsi_da.h> #include <cam/ctl/ctl_io.h> #include <cam/ctl/ctl.h> #include <cam/ctl/ctl_frontend.h> #include <cam/ctl/ctl_frontend_internal.h> #include <cam/ctl/ctl_util.h> #include <cam/ctl/ctl_backend.h> #include <cam/ctl/ctl_ioctl.h> #include <cam/ctl/ctl_ha.h> #include <cam/ctl/ctl_private.h> #include <cam/ctl/ctl_debug.h> #include <cam/ctl/ctl_scsi_all.h> #include <cam/ctl/ctl_error.h> struct ctl_softc *control_softc = NULL; /* * The default is to run with CTL_DONE_THREAD turned on. Completed * transactions are queued for processing by the CTL work thread. When * CTL_DONE_THREAD is not defined, completed transactions are processed in * the caller's context. */ #define CTL_DONE_THREAD /* * * Use the serial number and device ID provided by the backend, rather than * * making up our own. * */ #define CTL_USE_BACKEND_SN /* * Size and alignment macros needed for Copan-specific HA hardware. These * can go away when the HA code is re-written, and uses busdma for any * hardware. */ #define CTL_ALIGN_8B(target, source, type) \ if (((uint32_t)source & 0x7) != 0) \ target = (type)(source + (0x8 - ((uint32_t)source & 0x7)));\ else \ target = (type)source; #define CTL_SIZE_8B(target, size) \ if ((size & 0x7) != 0) \ target = size + (0x8 - (size & 0x7)); \ else \ target = size; #define CTL_ALIGN_8B_MARGIN 16 /* * Template mode pages. */ /* * Note that these are default values only. The actual values will be * filled in when the user does a mode sense. */ static struct copan_power_subpage power_page_default = { /*page_code*/ PWR_PAGE_CODE | SMPH_SPF, /*subpage*/ PWR_SUBPAGE_CODE, /*page_length*/ {(sizeof(struct copan_power_subpage) - 4) & 0xff00, (sizeof(struct copan_power_subpage) - 4) & 0x00ff}, /*page_version*/ PWR_VERSION, /* total_luns */ 26, /* max_active_luns*/ PWR_DFLT_MAX_LUNS, /*reserved*/ {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0} }; static struct copan_power_subpage power_page_changeable = { /*page_code*/ PWR_PAGE_CODE | SMPH_SPF, /*subpage*/ PWR_SUBPAGE_CODE, /*page_length*/ {(sizeof(struct copan_power_subpage) - 4) & 0xff00, (sizeof(struct copan_power_subpage) - 4) & 0x00ff}, /*page_version*/ 0, /* total_luns */ 0, /* max_active_luns*/ 0, /*reserved*/ {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0} }; static struct copan_aps_subpage aps_page_default = { APS_PAGE_CODE | SMPH_SPF, //page_code APS_SUBPAGE_CODE, //subpage {(sizeof(struct copan_aps_subpage) - 4) & 0xff00, (sizeof(struct copan_aps_subpage) - 4) & 0x00ff}, //page_length APS_VERSION, //page_version 0, //lock_active {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0} //reserved }; static struct copan_aps_subpage aps_page_changeable = { APS_PAGE_CODE | SMPH_SPF, //page_code APS_SUBPAGE_CODE, //subpage {(sizeof(struct copan_aps_subpage) - 4) & 0xff00, (sizeof(struct copan_aps_subpage) - 4) & 0x00ff}, //page_length 0, //page_version 0, //lock_active {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0} //reserved }; static struct copan_debugconf_subpage debugconf_page_default = { DBGCNF_PAGE_CODE | SMPH_SPF, /* page_code */ DBGCNF_SUBPAGE_CODE, /* subpage */ {(sizeof(struct copan_debugconf_subpage) - 4) >> 8, (sizeof(struct copan_debugconf_subpage) - 4) >> 0}, /* page_length */ DBGCNF_VERSION, /* page_version */ {CTL_TIME_IO_DEFAULT_SECS>>8, CTL_TIME_IO_DEFAULT_SECS>>0}, /* ctl_time_io_secs */ }; static struct copan_debugconf_subpage debugconf_page_changeable = { DBGCNF_PAGE_CODE | SMPH_SPF, /* page_code */ DBGCNF_SUBPAGE_CODE, /* subpage */ {(sizeof(struct copan_debugconf_subpage) - 4) >> 8, (sizeof(struct copan_debugconf_subpage) - 4) >> 0}, /* page_length */ 0, /* page_version */ {0xff,0xff}, /* ctl_time_io_secs */ }; static struct scsi_format_page format_page_default = { /*page_code*/SMS_FORMAT_DEVICE_PAGE, /*page_length*/sizeof(struct scsi_format_page) - 2, /*tracks_per_zone*/ {0, 0}, /*alt_sectors_per_zone*/ {0, 0}, /*alt_tracks_per_zone*/ {0, 0}, /*alt_tracks_per_lun*/ {0, 0}, /*sectors_per_track*/ {(CTL_DEFAULT_SECTORS_PER_TRACK >> 8) & 0xff, CTL_DEFAULT_SECTORS_PER_TRACK & 0xff}, /*bytes_per_sector*/ {0, 0}, /*interleave*/ {0, 0}, /*track_skew*/ {0, 0}, /*cylinder_skew*/ {0, 0}, /*flags*/ SFP_HSEC, /*reserved*/ {0, 0, 0} }; static struct scsi_format_page format_page_changeable = { /*page_code*/SMS_FORMAT_DEVICE_PAGE, /*page_length*/sizeof(struct scsi_format_page) - 2, /*tracks_per_zone*/ {0, 0}, /*alt_sectors_per_zone*/ {0, 0}, /*alt_tracks_per_zone*/ {0, 0}, /*alt_tracks_per_lun*/ {0, 0}, /*sectors_per_track*/ {0, 0}, /*bytes_per_sector*/ {0, 0}, /*interleave*/ {0, 0}, /*track_skew*/ {0, 0}, /*cylinder_skew*/ {0, 0}, /*flags*/ 0, /*reserved*/ {0, 0, 0} }; static struct scsi_rigid_disk_page rigid_disk_page_default = { /*page_code*/SMS_RIGID_DISK_PAGE, /*page_length*/sizeof(struct scsi_rigid_disk_page) - 2, /*cylinders*/ {0, 0, 0}, /*heads*/ CTL_DEFAULT_HEADS, /*start_write_precomp*/ {0, 0, 0}, /*start_reduced_current*/ {0, 0, 0}, /*step_rate*/ {0, 0}, /*landing_zone_cylinder*/ {0, 0, 0}, /*rpl*/ SRDP_RPL_DISABLED, /*rotational_offset*/ 0, /*reserved1*/ 0, /*rotation_rate*/ {(CTL_DEFAULT_ROTATION_RATE >> 8) & 0xff, CTL_DEFAULT_ROTATION_RATE & 0xff}, /*reserved2*/ {0, 0} }; static struct scsi_rigid_disk_page rigid_disk_page_changeable = { /*page_code*/SMS_RIGID_DISK_PAGE, /*page_length*/sizeof(struct scsi_rigid_disk_page) - 2, /*cylinders*/ {0, 0, 0}, /*heads*/ 0, /*start_write_precomp*/ {0, 0, 0}, /*start_reduced_current*/ {0, 0, 0}, /*step_rate*/ {0, 0}, /*landing_zone_cylinder*/ {0, 0, 0}, /*rpl*/ 0, /*rotational_offset*/ 0, /*reserved1*/ 0, /*rotation_rate*/ {0, 0}, /*reserved2*/ {0, 0} }; static struct scsi_caching_page caching_page_default = { /*page_code*/SMS_CACHING_PAGE, /*page_length*/sizeof(struct scsi_caching_page) - 2, /*flags1*/ SCP_DISC | SCP_WCE, /*ret_priority*/ 0, /*disable_pf_transfer_len*/ {0xff, 0xff}, /*min_prefetch*/ {0, 0}, /*max_prefetch*/ {0xff, 0xff}, /*max_pf_ceiling*/ {0xff, 0xff}, /*flags2*/ 0, /*cache_segments*/ 0, /*cache_seg_size*/ {0, 0}, /*reserved*/ 0, /*non_cache_seg_size*/ {0, 0, 0} }; static struct scsi_caching_page caching_page_changeable = { /*page_code*/SMS_CACHING_PAGE, /*page_length*/sizeof(struct scsi_caching_page) - 2, /*flags1*/ 0, /*ret_priority*/ 0, /*disable_pf_transfer_len*/ {0, 0}, /*min_prefetch*/ {0, 0}, /*max_prefetch*/ {0, 0}, /*max_pf_ceiling*/ {0, 0}, /*flags2*/ 0, /*cache_segments*/ 0, /*cache_seg_size*/ {0, 0}, /*reserved*/ 0, /*non_cache_seg_size*/ {0, 0, 0} }; static struct scsi_control_page control_page_default = { /*page_code*/SMS_CONTROL_MODE_PAGE, /*page_length*/sizeof(struct scsi_control_page) - 2, /*rlec*/0, /*queue_flags*/0, /*eca_and_aen*/0, /*reserved*/0, /*aen_holdoff_period*/{0, 0} }; static struct scsi_control_page control_page_changeable = { /*page_code*/SMS_CONTROL_MODE_PAGE, /*page_length*/sizeof(struct scsi_control_page) - 2, /*rlec*/SCP_DSENSE, /*queue_flags*/0, /*eca_and_aen*/0, /*reserved*/0, /*aen_holdoff_period*/{0, 0} }; /* * XXX KDM move these into the softc. */ static int rcv_sync_msg; static int persis_offset; static uint8_t ctl_pause_rtr; static int ctl_is_single; static int index_to_aps_page; int ctl_disable = 0; SYSCTL_NODE(_kern_cam, OID_AUTO, ctl, CTLFLAG_RD, 0, "CAM Target Layer"); SYSCTL_INT(_kern_cam_ctl, OID_AUTO, disable, CTLFLAG_RDTUN, &ctl_disable, 0, "Disable CTL"); TUNABLE_INT("kern.cam.ctl.disable", &ctl_disable); /* * Serial number (0x80), device id (0x83), and supported pages (0x00) */ #define SCSI_EVPD_NUM_SUPPORTED_PAGES 3 static void ctl_isc_event_handler(ctl_ha_channel chanel, ctl_ha_event event, int param); static void ctl_copy_sense_data(union ctl_ha_msg *src, union ctl_io *dest); static void ctl_init(void); void ctl_shutdown(void); static int ctl_open(struct cdev *dev, int flags, int fmt, struct thread *td); static int ctl_close(struct cdev *dev, int flags, int fmt, struct thread *td); static void ctl_ioctl_online(void *arg); static void ctl_ioctl_offline(void *arg); static int ctl_ioctl_targ_enable(void *arg, struct ctl_id targ_id); static int ctl_ioctl_targ_disable(void *arg, struct ctl_id targ_id); static int ctl_ioctl_lun_enable(void *arg, struct ctl_id targ_id, int lun_id); static int ctl_ioctl_lun_disable(void *arg, struct ctl_id targ_id, int lun_id); static int ctl_ioctl_do_datamove(struct ctl_scsiio *ctsio); static int ctl_serialize_other_sc_cmd(struct ctl_scsiio *ctsio, int have_lock); static int ctl_ioctl_submit_wait(union ctl_io *io); static void ctl_ioctl_datamove(union ctl_io *io); static void ctl_ioctl_done(union ctl_io *io); static void ctl_ioctl_hard_startstop_callback(void *arg, struct cfi_metatask *metatask); static void ctl_ioctl_bbrread_callback(void *arg,struct cfi_metatask *metatask); static int ctl_ioctl_fill_ooa(struct ctl_lun *lun, uint32_t *cur_fill_num, struct ctl_ooa *ooa_hdr); static int ctl_ioctl(struct cdev *dev, u_long cmd, caddr_t addr, int flag, struct thread *td); uint32_t ctl_get_resindex(struct ctl_nexus *nexus); uint32_t ctl_port_idx(int port_num); #ifdef unused static union ctl_io *ctl_malloc_io(ctl_io_type io_type, uint32_t targ_port, uint32_t targ_target, uint32_t targ_lun, int can_wait); static void ctl_kfree_io(union ctl_io *io); #endif /* unused */ static void ctl_free_io_internal(union ctl_io *io, int have_lock); static int ctl_alloc_lun(struct ctl_softc *ctl_softc, struct ctl_lun *lun, struct ctl_be_lun *be_lun, struct ctl_id target_id); static int ctl_free_lun(struct ctl_lun *lun); static void ctl_create_lun(struct ctl_be_lun *be_lun); /** static void ctl_failover_change_pages(struct ctl_softc *softc, struct ctl_scsiio *ctsio, int master); **/ static int ctl_do_mode_select(union ctl_io *io); static int ctl_pro_preempt(struct ctl_softc *softc, struct ctl_lun *lun, uint64_t res_key, uint64_t sa_res_key, uint8_t type, uint32_t residx, struct ctl_scsiio *ctsio, struct scsi_per_res_out *cdb, struct scsi_per_res_out_parms* param); static void ctl_pro_preempt_other(struct ctl_lun *lun, union ctl_ha_msg *msg); static void ctl_hndl_per_res_out_on_other_sc(union ctl_ha_msg *msg); static int ctl_inquiry_evpd_supported(struct ctl_scsiio *ctsio, int alloc_len); static int ctl_inquiry_evpd_serial(struct ctl_scsiio *ctsio, int alloc_len); static int ctl_inquiry_evpd_devid(struct ctl_scsiio *ctsio, int alloc_len); static int ctl_inquiry_evpd(struct ctl_scsiio *ctsio); static int ctl_inquiry_std(struct ctl_scsiio *ctsio); static int ctl_get_lba_len(union ctl_io *io, uint64_t *lba, uint32_t *len); static ctl_action ctl_extent_check(union ctl_io *io1, union ctl_io *io2); static ctl_action ctl_check_for_blockage(union ctl_io *pending_io, union ctl_io *ooa_io); static ctl_action ctl_check_ooa(struct ctl_lun *lun, union ctl_io *pending_io, union ctl_io *starting_io); static int ctl_check_blocked(struct ctl_lun *lun); static int ctl_scsiio_lun_check(struct ctl_softc *ctl_softc, struct ctl_lun *lun, struct ctl_cmd_entry *entry, struct ctl_scsiio *ctsio); //static int ctl_check_rtr(union ctl_io *pending_io, struct ctl_softc *softc); static void ctl_failover(void); static int ctl_scsiio_precheck(struct ctl_softc *ctl_softc, struct ctl_scsiio *ctsio); static int ctl_scsiio(struct ctl_scsiio *ctsio); static int ctl_bus_reset(struct ctl_softc *ctl_softc, union ctl_io *io); static int ctl_target_reset(struct ctl_softc *ctl_softc, union ctl_io *io, ctl_ua_type ua_type); static int ctl_lun_reset(struct ctl_lun *lun, union ctl_io *io, ctl_ua_type ua_type); static int ctl_abort_task(union ctl_io *io); static void ctl_run_task_queue(struct ctl_softc *ctl_softc); #ifdef CTL_IO_DELAY static void ctl_datamove_timer_wakeup(void *arg); static void ctl_done_timer_wakeup(void *arg); #endif /* CTL_IO_DELAY */ static void ctl_send_datamove_done(union ctl_io *io, int have_lock); static void ctl_datamove_remote_write_cb(struct ctl_ha_dt_req *rq); static int ctl_datamove_remote_dm_write_cb(union ctl_io *io); static void ctl_datamove_remote_write(union ctl_io *io); static int ctl_datamove_remote_dm_read_cb(union ctl_io *io); static void ctl_datamove_remote_read_cb(struct ctl_ha_dt_req *rq); static int ctl_datamove_remote_sgl_setup(union ctl_io *io); static int ctl_datamove_remote_xfer(union ctl_io *io, unsigned command, ctl_ha_dt_cb callback); static void ctl_datamove_remote_read(union ctl_io *io); static void ctl_datamove_remote(union ctl_io *io); static int ctl_process_done(union ctl_io *io, int have_lock); static void ctl_work_thread(void *arg); /* * Load the serialization table. This isn't very pretty, but is probably * the easiest way to do it. */ #include "ctl_ser_table.c" /* * We only need to define open, close and ioctl routines for this driver. */ static struct cdevsw ctl_cdevsw = { .d_version = D_VERSION, .d_flags = 0, .d_open = ctl_open, .d_close = ctl_close, .d_ioctl = ctl_ioctl, .d_name = "ctl", }; MALLOC_DEFINE(M_CTL, "ctlmem", "Memory used for CTL"); /* * If we have the CAM SIM, we may or may not have another SIM that will * cause CTL to get initialized. If not, we need to initialize it. */ SYSINIT(ctl_init, SI_SUB_CONFIGURE, SI_ORDER_THIRD, ctl_init, NULL); static void ctl_isc_handler_finish_xfer(struct ctl_softc *ctl_softc, union ctl_ha_msg *msg_info) { struct ctl_scsiio *ctsio; if (msg_info->hdr.original_sc == NULL) { printf("%s: original_sc == NULL!\n", __func__); /* XXX KDM now what? */ return; } ctsio = &msg_info->hdr.original_sc->scsiio; ctsio->io_hdr.flags |= CTL_FLAG_IO_ACTIVE; ctsio->io_hdr.msg_type = CTL_MSG_FINISH_IO; ctsio->io_hdr.status = msg_info->hdr.status; ctsio->scsi_status = msg_info->scsi.scsi_status; ctsio->sense_len = msg_info->scsi.sense_len; ctsio->sense_residual = msg_info->scsi.sense_residual; ctsio->residual = msg_info->scsi.residual; memcpy(&ctsio->sense_data, &msg_info->scsi.sense_data, sizeof(ctsio->sense_data)); memcpy(&ctsio->io_hdr.ctl_private[CTL_PRIV_LBA_LEN].bytes, &msg_info->scsi.lbalen, sizeof(msg_info->scsi.lbalen));; STAILQ_INSERT_TAIL(&ctl_softc->isc_queue, &ctsio->io_hdr, links); ctl_wakeup_thread(); } static void ctl_isc_handler_finish_ser_only(struct ctl_softc *ctl_softc, union ctl_ha_msg *msg_info) { struct ctl_scsiio *ctsio; if (msg_info->hdr.serializing_sc == NULL) { printf("%s: serializing_sc == NULL!\n", __func__); /* XXX KDM now what? */ return; } ctsio = &msg_info->hdr.serializing_sc->scsiio; #if 0 /* * Attempt to catch the situation where an I/O has * been freed, and we're using it again. */ if (ctsio->io_hdr.io_type == 0xff) { union ctl_io *tmp_io; tmp_io = (union ctl_io *)ctsio; printf("%s: %p use after free!\n", __func__, ctsio); printf("%s: type %d msg %d cdb %x iptl: " "%d:%d:%d:%d tag 0x%04x " "flag %#x status %x\n", __func__, tmp_io->io_hdr.io_type, tmp_io->io_hdr.msg_type, tmp_io->scsiio.cdb[0], tmp_io->io_hdr.nexus.initid.id, tmp_io->io_hdr.nexus.targ_port, tmp_io->io_hdr.nexus.targ_target.id, tmp_io->io_hdr.nexus.targ_lun, (tmp_io->io_hdr.io_type == CTL_IO_TASK) ? tmp_io->taskio.tag_num : tmp_io->scsiio.tag_num, tmp_io->io_hdr.flags, tmp_io->io_hdr.status); } #endif ctsio->io_hdr.msg_type = CTL_MSG_FINISH_IO; STAILQ_INSERT_TAIL(&ctl_softc->isc_queue, &ctsio->io_hdr, links); ctl_wakeup_thread(); } /* * ISC (Inter Shelf Communication) event handler. Events from the HA * subsystem come in here. */ static void ctl_isc_event_handler(ctl_ha_channel channel, ctl_ha_event event, int param) { struct ctl_softc *ctl_softc; union ctl_io *io; struct ctl_prio *presio; ctl_ha_status isc_status; ctl_softc = control_softc; io = NULL; #if 0 printf("CTL: Isc Msg event %d\n", event); #endif if (event == CTL_HA_EVT_MSG_RECV) { union ctl_ha_msg msg_info; isc_status = ctl_ha_msg_recv(CTL_HA_CHAN_CTL, &msg_info, sizeof(msg_info), /*wait*/ 0); #if 0 printf("CTL: msg_type %d\n", msg_info.msg_type); #endif if (isc_status != 0) { printf("Error receiving message, status = %d\n", isc_status); return; } mtx_lock(&ctl_softc->ctl_lock); switch (msg_info.hdr.msg_type) { case CTL_MSG_SERIALIZE: #if 0 printf("Serialize\n"); #endif io = ctl_alloc_io((void *)ctl_softc->othersc_pool); if (io == NULL) { printf("ctl_isc_event_handler: can't allocate " "ctl_io!\n"); /* Bad Juju */ /* Need to set busy and send msg back */ mtx_unlock(&ctl_softc->ctl_lock); msg_info.hdr.msg_type = CTL_MSG_BAD_JUJU; msg_info.hdr.status = CTL_SCSI_ERROR; msg_info.scsi.scsi_status = SCSI_STATUS_BUSY; msg_info.scsi.sense_len = 0; if (ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg_info, sizeof(msg_info), 0) > CTL_HA_STATUS_SUCCESS){ } goto bailout; } ctl_zero_io(io); // populate ctsio from msg_info io->io_hdr.io_type = CTL_IO_SCSI; io->io_hdr.msg_type = CTL_MSG_SERIALIZE; io->io_hdr.original_sc = msg_info.hdr.original_sc; #if 0 printf("pOrig %x\n", (int)msg_info.original_sc); #endif io->io_hdr.flags |= CTL_FLAG_FROM_OTHER_SC | CTL_FLAG_IO_ACTIVE; /* * If we're in serialization-only mode, we don't * want to go through full done processing. Thus * the COPY flag. * * XXX KDM add another flag that is more specific. */ if (ctl_softc->ha_mode == CTL_HA_MODE_SER_ONLY) io->io_hdr.flags |= CTL_FLAG_INT_COPY; io->io_hdr.nexus = msg_info.hdr.nexus; #if 0 printf("targ %d, port %d, iid %d, lun %d\n", io->io_hdr.nexus.targ_target.id, io->io_hdr.nexus.targ_port, io->io_hdr.nexus.initid.id, io->io_hdr.nexus.targ_lun); #endif io->scsiio.tag_num = msg_info.scsi.tag_num; io->scsiio.tag_type = msg_info.scsi.tag_type; memcpy(io->scsiio.cdb, msg_info.scsi.cdb, CTL_MAX_CDBLEN); if (ctl_softc->ha_mode == CTL_HA_MODE_XFER) { struct ctl_cmd_entry *entry; uint8_t opcode; opcode = io->scsiio.cdb[0]; entry = &ctl_cmd_table[opcode]; io->io_hdr.flags &= ~CTL_FLAG_DATA_MASK; io->io_hdr.flags |= entry->flags & CTL_FLAG_DATA_MASK; } STAILQ_INSERT_TAIL(&ctl_softc->isc_queue, &io->io_hdr, links); ctl_wakeup_thread(); break; /* Performed on the Originating SC, XFER mode only */ case CTL_MSG_DATAMOVE: { struct ctl_sg_entry *sgl; int i, j; io = msg_info.hdr.original_sc; if (io == NULL) { printf("%s: original_sc == NULL!\n", __func__); /* XXX KDM do something here */ break; } io->io_hdr.msg_type = CTL_MSG_DATAMOVE; io->io_hdr.flags |= CTL_FLAG_IO_ACTIVE; /* * Keep track of this, we need to send it back over * when the datamove is complete. */ io->io_hdr.serializing_sc = msg_info.hdr.serializing_sc; if (msg_info.dt.sg_sequence == 0) { /* * XXX KDM we use the preallocated S/G list * here, but we'll need to change this to * dynamic allocation if we need larger S/G * lists. */ if (msg_info.dt.kern_sg_entries > sizeof(io->io_hdr.remote_sglist) / sizeof(io->io_hdr.remote_sglist[0])) { printf("%s: number of S/G entries " "needed %u > allocated num %zd\n", __func__, msg_info.dt.kern_sg_entries, sizeof(io->io_hdr.remote_sglist)/ sizeof(io->io_hdr.remote_sglist[0])); /* * XXX KDM send a message back to * the other side to shut down the * DMA. The error will come back * through via the normal channel. */ break; } sgl = io->io_hdr.remote_sglist; memset(sgl, 0, sizeof(io->io_hdr.remote_sglist)); io->scsiio.kern_data_ptr = (uint8_t *)sgl; io->scsiio.kern_sg_entries = msg_info.dt.kern_sg_entries; io->scsiio.rem_sg_entries = msg_info.dt.kern_sg_entries; io->scsiio.kern_data_len = msg_info.dt.kern_data_len; io->scsiio.kern_total_len = msg_info.dt.kern_total_len; io->scsiio.kern_data_resid = msg_info.dt.kern_data_resid; io->scsiio.kern_rel_offset = msg_info.dt.kern_rel_offset; /* * Clear out per-DMA flags. */ io->io_hdr.flags &= ~CTL_FLAG_RDMA_MASK; /* * Add per-DMA flags that are set for this * particular DMA request. */ io->io_hdr.flags |= msg_info.dt.flags & CTL_FLAG_RDMA_MASK; } else sgl = (struct ctl_sg_entry *) io->scsiio.kern_data_ptr; for (i = msg_info.dt.sent_sg_entries, j = 0; i < (msg_info.dt.sent_sg_entries + msg_info.dt.cur_sg_entries); i++, j++) { sgl[i].addr = msg_info.dt.sg_list[j].addr; sgl[i].len = msg_info.dt.sg_list[j].len; #if 0 printf("%s: L: %p,%d -> %p,%d j=%d, i=%d\n", __func__, msg_info.dt.sg_list[j].addr, msg_info.dt.sg_list[j].len, sgl[i].addr, sgl[i].len, j, i); #endif } #if 0 memcpy(&sgl[msg_info.dt.sent_sg_entries], msg_info.dt.sg_list, sizeof(*sgl) * msg_info.dt.cur_sg_entries); #endif /* * If this is the last piece of the I/O, we've got * the full S/G list. Queue processing in the thread. * Otherwise wait for the next piece. */ if (msg_info.dt.sg_last != 0) { STAILQ_INSERT_TAIL(&ctl_softc->isc_queue, &io->io_hdr, links); ctl_wakeup_thread(); } break; } /* Performed on the Serializing (primary) SC, XFER mode only */ case CTL_MSG_DATAMOVE_DONE: { if (msg_info.hdr.serializing_sc == NULL) { printf("%s: serializing_sc == NULL!\n", __func__); /* XXX KDM now what? */ break; } /* * We grab the sense information here in case * there was a failure, so we can return status * back to the initiator. */ io = msg_info.hdr.serializing_sc; io->io_hdr.msg_type = CTL_MSG_DATAMOVE_DONE; io->io_hdr.status = msg_info.hdr.status; io->scsiio.scsi_status = msg_info.scsi.scsi_status; io->scsiio.sense_len = msg_info.scsi.sense_len; io->scsiio.sense_residual =msg_info.scsi.sense_residual; io->io_hdr.port_status = msg_info.scsi.fetd_status; io->scsiio.residual = msg_info.scsi.residual; memcpy(&io->scsiio.sense_data,&msg_info.scsi.sense_data, sizeof(io->scsiio.sense_data)); STAILQ_INSERT_TAIL(&ctl_softc->isc_queue, &io->io_hdr, links); ctl_wakeup_thread(); break; } /* Preformed on Originating SC, SER_ONLY mode */ case CTL_MSG_R2R: io = msg_info.hdr.original_sc; if (io == NULL) { printf("%s: Major Bummer\n", __func__); mtx_unlock(&ctl_softc->ctl_lock); return; } else { #if 0 printf("pOrig %x\n",(int) ctsio); #endif } io->io_hdr.msg_type = CTL_MSG_R2R; io->io_hdr.serializing_sc = msg_info.hdr.serializing_sc; STAILQ_INSERT_TAIL(&ctl_softc->isc_queue, &io->io_hdr, links); ctl_wakeup_thread(); break; /* * Performed on Serializing(i.e. primary SC) SC in SER_ONLY * mode. * Performed on the Originating (i.e. secondary) SC in XFER * mode */ case CTL_MSG_FINISH_IO: if (ctl_softc->ha_mode == CTL_HA_MODE_XFER) ctl_isc_handler_finish_xfer(ctl_softc, &msg_info); else ctl_isc_handler_finish_ser_only(ctl_softc, &msg_info); break; /* Preformed on Originating SC */ case CTL_MSG_BAD_JUJU: io = msg_info.hdr.original_sc; if (io == NULL) { printf("%s: Bad JUJU!, original_sc is NULL!\n", __func__); break; } ctl_copy_sense_data(&msg_info, io); /* * IO should have already been cleaned up on other * SC so clear this flag so we won't send a message * back to finish the IO there. */ io->io_hdr.flags &= ~CTL_FLAG_SENT_2OTHER_SC; io->io_hdr.flags |= CTL_FLAG_IO_ACTIVE; /* io = msg_info.hdr.serializing_sc; */ io->io_hdr.msg_type = CTL_MSG_BAD_JUJU; STAILQ_INSERT_TAIL(&ctl_softc->isc_queue, &io->io_hdr, links); ctl_wakeup_thread(); break; /* Handle resets sent from the other side */ case CTL_MSG_MANAGE_TASKS: { struct ctl_taskio *taskio; taskio = (struct ctl_taskio *)ctl_alloc_io( (void *)ctl_softc->othersc_pool); if (taskio == NULL) { printf("ctl_isc_event_handler: can't allocate " "ctl_io!\n"); /* Bad Juju */ /* should I just call the proper reset func here??? */ mtx_unlock(&ctl_softc->ctl_lock); goto bailout; } ctl_zero_io((union ctl_io *)taskio); taskio->io_hdr.io_type = CTL_IO_TASK; taskio->io_hdr.flags |= CTL_FLAG_FROM_OTHER_SC; taskio->io_hdr.nexus = msg_info.hdr.nexus; taskio->task_action = msg_info.task.task_action; taskio->tag_num = msg_info.task.tag_num; taskio->tag_type = msg_info.task.tag_type; #ifdef CTL_TIME_IO taskio->io_hdr.start_time = time_uptime; getbintime(&taskio->io_hdr.start_bt); #if 0 cs_prof_gettime(&taskio->io_hdr.start_ticks); #endif #endif /* CTL_TIME_IO */ STAILQ_INSERT_TAIL(&ctl_softc->task_queue, &taskio->io_hdr, links); ctl_softc->flags |= CTL_FLAG_TASK_PENDING; ctl_wakeup_thread(); break; } /* Persistent Reserve action which needs attention */ case CTL_MSG_PERS_ACTION: presio = (struct ctl_prio *)ctl_alloc_io( (void *)ctl_softc->othersc_pool); if (presio == NULL) { printf("ctl_isc_event_handler: can't allocate " "ctl_io!\n"); /* Bad Juju */ /* Need to set busy and send msg back */ mtx_unlock(&ctl_softc->ctl_lock); goto bailout; } ctl_zero_io((union ctl_io *)presio); presio->io_hdr.msg_type = CTL_MSG_PERS_ACTION; presio->pr_msg = msg_info.pr; STAILQ_INSERT_TAIL(&ctl_softc->isc_queue, &presio->io_hdr, links); ctl_wakeup_thread(); break; case CTL_MSG_SYNC_FE: rcv_sync_msg = 1; break; case CTL_MSG_APS_LOCK: { // It's quicker to execute this then to // queue it. struct ctl_lun *lun; struct ctl_page_index *page_index; struct copan_aps_subpage *current_sp; lun = ctl_softc->ctl_luns[msg_info.hdr.nexus.targ_lun]; page_index = &lun->mode_pages.index[index_to_aps_page]; current_sp = (struct copan_aps_subpage *) (page_index->page_data + (page_index->page_len * CTL_PAGE_CURRENT)); current_sp->lock_active = msg_info.aps.lock_flag; break; } default: printf("How did I get here?\n"); } mtx_unlock(&ctl_softc->ctl_lock); } else if (event == CTL_HA_EVT_MSG_SENT) { if (param != CTL_HA_STATUS_SUCCESS) { printf("Bad status from ctl_ha_msg_send status %d\n", param); } return; } else if (event == CTL_HA_EVT_DISCONNECT) { printf("CTL: Got a disconnect from Isc\n"); return; } else { printf("ctl_isc_event_handler: Unknown event %d\n", event); return; } bailout: return; } static void ctl_copy_sense_data(union ctl_ha_msg *src, union ctl_io *dest) { struct scsi_sense_data *sense; sense = &dest->scsiio.sense_data; bcopy(&src->scsi.sense_data, sense, sizeof(*sense)); dest->scsiio.scsi_status = src->scsi.scsi_status; dest->scsiio.sense_len = src->scsi.sense_len; dest->io_hdr.status = src->hdr.status; } static void ctl_init(void) { struct ctl_softc *softc; struct ctl_io_pool *internal_pool, *emergency_pool, *other_pool; struct ctl_frontend *fe; struct ctl_lun *lun; uint8_t sc_id =0; #if 0 int i; #endif int retval; //int isc_retval; retval = 0; ctl_pause_rtr = 0; rcv_sync_msg = 0; /* If we're disabled, don't initialize. */ if (ctl_disable != 0) return; control_softc = malloc(sizeof(*control_softc), M_DEVBUF, M_WAITOK); softc = control_softc; memset(softc, 0, sizeof(*softc)); softc->dev = make_dev(&ctl_cdevsw, 0, UID_ROOT, GID_OPERATOR, 0600, "cam/ctl"); softc->dev->si_drv1 = softc; /* * By default, return a "bad LUN" peripheral qualifier for unknown * LUNs. The user can override this default using the tunable or * sysctl. See the comment in ctl_inquiry_std() for more details. */ softc->inquiry_pq_no_lun = 1; TUNABLE_INT_FETCH("kern.cam.ctl.inquiry_pq_no_lun", &softc->inquiry_pq_no_lun); sysctl_ctx_init(&softc->sysctl_ctx); softc->sysctl_tree = SYSCTL_ADD_NODE(&softc->sysctl_ctx, SYSCTL_STATIC_CHILDREN(_kern_cam), OID_AUTO, "ctl", CTLFLAG_RD, 0, "CAM Target Layer"); if (softc->sysctl_tree == NULL) { printf("%s: unable to allocate sysctl tree\n", __func__); destroy_dev(softc->dev); free(control_softc, M_DEVBUF); control_softc = NULL; return; } SYSCTL_ADD_INT(&softc->sysctl_ctx, SYSCTL_CHILDREN(softc->sysctl_tree), OID_AUTO, "inquiry_pq_no_lun", CTLFLAG_RW, &softc->inquiry_pq_no_lun, 0, "Report no lun possible for invalid LUNs"); mtx_init(&softc->ctl_lock, "CTL mutex", NULL, MTX_DEF); softc->open_count = 0; /* * Default to actually sending a SYNCHRONIZE CACHE command down to * the drive. */ softc->flags = CTL_FLAG_REAL_SYNC; /* * In Copan's HA scheme, the "master" and "slave" roles are * figured out through the slot the controller is in. Although it * is an active/active system, someone has to be in charge. */ #ifdef NEEDTOPORT scmicro_rw(SCMICRO_GET_SHELF_ID, &sc_id); #endif if (sc_id == 0) { softc->flags |= CTL_FLAG_MASTER_SHELF; persis_offset = 0; } else persis_offset = CTL_MAX_INITIATORS; /* * XXX KDM need to figure out where we want to get our target ID * and WWID. Is it different on each port? */ softc->target.id = 0; softc->target.wwid[0] = 0x12345678; softc->target.wwid[1] = 0x87654321; STAILQ_INIT(&softc->lun_list); STAILQ_INIT(&softc->pending_lun_queue); STAILQ_INIT(&softc->task_queue); STAILQ_INIT(&softc->incoming_queue); STAILQ_INIT(&softc->rtr_queue); STAILQ_INIT(&softc->done_queue); STAILQ_INIT(&softc->isc_queue); STAILQ_INIT(&softc->fe_list); STAILQ_INIT(&softc->be_list); STAILQ_INIT(&softc->io_pools); lun = &softc->lun; /* * We don't bother calling these with ctl_lock held here, because, * in theory, no one else can try to do anything while we're in our * module init routine. */ if (ctl_pool_create(softc, CTL_POOL_INTERNAL, CTL_POOL_ENTRIES_INTERNAL, &internal_pool)!= 0){ printf("ctl: can't allocate %d entry internal pool, " "exiting\n", CTL_POOL_ENTRIES_INTERNAL); return; } if (ctl_pool_create(softc, CTL_POOL_EMERGENCY, CTL_POOL_ENTRIES_EMERGENCY, &emergency_pool) != 0) { printf("ctl: can't allocate %d entry emergency pool, " "exiting\n", CTL_POOL_ENTRIES_EMERGENCY); ctl_pool_free(softc, internal_pool); return; } if (ctl_pool_create(softc, CTL_POOL_4OTHERSC, CTL_POOL_ENTRIES_OTHER_SC, &other_pool) != 0) { printf("ctl: can't allocate %d entry other SC pool, " "exiting\n", CTL_POOL_ENTRIES_OTHER_SC); ctl_pool_free(softc, internal_pool); ctl_pool_free(softc, emergency_pool); return; } softc->internal_pool = internal_pool; softc->emergency_pool = emergency_pool; softc->othersc_pool = other_pool; ctl_pool_acquire(internal_pool); ctl_pool_acquire(emergency_pool); ctl_pool_acquire(other_pool); /* * We used to allocate a processor LUN here. The new scheme is to * just let the user allocate LUNs as he sees fit. */ #if 0 mtx_lock(&softc->ctl_lock); ctl_alloc_lun(softc, lun, /*be_lun*/NULL, /*target*/softc->target); mtx_unlock(&softc->ctl_lock); #endif if (kproc_create(ctl_work_thread, softc, &softc->work_thread, 0, 0, "ctl_thrd") != 0) { printf("error creating CTL work thread!\n"); ctl_free_lun(lun); ctl_pool_free(softc, internal_pool); ctl_pool_free(softc, emergency_pool); ctl_pool_free(softc, other_pool); return; } printf("ctl: CAM Target Layer loaded\n"); /* * Initialize the initiator and portname mappings */ memset(softc->wwpn_iid, 0, sizeof(softc->wwpn_iid)); /* * Initialize the ioctl front end. */ fe = &softc->ioctl_info.fe; sprintf(softc->ioctl_info.port_name, "CTL ioctl"); fe->port_type = CTL_PORT_IOCTL; fe->num_requested_ctl_io = 100; fe->port_name = softc->ioctl_info.port_name; fe->port_online = ctl_ioctl_online; fe->port_offline = ctl_ioctl_offline; fe->onoff_arg = &softc->ioctl_info; fe->targ_enable = ctl_ioctl_targ_enable; fe->targ_disable = ctl_ioctl_targ_disable; fe->lun_enable = ctl_ioctl_lun_enable; fe->lun_disable = ctl_ioctl_lun_disable; fe->targ_lun_arg = &softc->ioctl_info; fe->fe_datamove = ctl_ioctl_datamove; fe->fe_done = ctl_ioctl_done; fe->max_targets = 15; fe->max_target_id = 15; if (ctl_frontend_register(&softc->ioctl_info.fe, (softc->flags & CTL_FLAG_MASTER_SHELF)) != 0) { printf("ctl: ioctl front end registration failed, will " "continue anyway\n"); } #ifdef CTL_IO_DELAY if (sizeof(struct callout) > CTL_TIMER_BYTES) { printf("sizeof(struct callout) %zd > CTL_TIMER_BYTES %zd\n", sizeof(struct callout), CTL_TIMER_BYTES); return; } #endif /* CTL_IO_DELAY */ } void ctl_shutdown(void) { struct ctl_softc *softc; struct ctl_lun *lun, *next_lun; struct ctl_io_pool *pool, *next_pool; softc = (struct ctl_softc *)control_softc; if (ctl_frontend_deregister(&softc->ioctl_info.fe) != 0) printf("ctl: ioctl front end deregistration failed\n"); mtx_lock(&softc->ctl_lock); /* * Free up each LUN. */ for (lun = STAILQ_FIRST(&softc->lun_list); lun != NULL; lun = next_lun){ next_lun = STAILQ_NEXT(lun, links); ctl_free_lun(lun); } /* * This will rip the rug out from under any FETDs or anyone else * that has a pool allocated. Since we increment our module * refcount any time someone outside the main CTL module allocates * a pool, we shouldn't have any problems here. The user won't be * able to unload the CTL module until client modules have * successfully unloaded. */ for (pool = STAILQ_FIRST(&softc->io_pools); pool != NULL; pool = next_pool) { next_pool = STAILQ_NEXT(pool, links); ctl_pool_free(softc, pool); } mtx_unlock(&softc->ctl_lock); #if 0 ctl_shutdown_thread(softc->work_thread); #endif mtx_destroy(&softc->ctl_lock); destroy_dev(softc->dev); sysctl_ctx_free(&softc->sysctl_ctx); free(control_softc, M_DEVBUF); control_softc = NULL; printf("ctl: CAM Target Layer unloaded\n"); } /* * XXX KDM should we do some access checks here? Bump a reference count to * prevent a CTL module from being unloaded while someone has it open? */ static int ctl_open(struct cdev *dev, int flags, int fmt, struct thread *td) { return (0); } static int ctl_close(struct cdev *dev, int flags, int fmt, struct thread *td) { return (0); } int ctl_port_enable(ctl_port_type port_type) { struct ctl_softc *softc; struct ctl_frontend *fe; if (ctl_is_single == 0) { union ctl_ha_msg msg_info; int isc_retval; #if 0 printf("%s: HA mode, synchronizing frontend enable\n", __func__); #endif msg_info.hdr.msg_type = CTL_MSG_SYNC_FE; if ((isc_retval=ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg_info, sizeof(msg_info), 1 )) > CTL_HA_STATUS_SUCCESS) { printf("Sync msg send error retval %d\n", isc_retval); } if (!rcv_sync_msg) { isc_retval=ctl_ha_msg_recv(CTL_HA_CHAN_CTL, &msg_info, sizeof(msg_info), 1); } #if 0 printf("CTL:Frontend Enable\n"); } else { printf("%s: single mode, skipping frontend synchronization\n", __func__); #endif } softc = control_softc; STAILQ_FOREACH(fe, &softc->fe_list, links) { if (port_type & fe->port_type) { #if 0 printf("port %d\n", fe->targ_port); #endif ctl_frontend_online(fe); } } return (0); } int ctl_port_disable(ctl_port_type port_type) { struct ctl_softc *softc; struct ctl_frontend *fe; softc = control_softc; STAILQ_FOREACH(fe, &softc->fe_list, links) { if (port_type & fe->port_type) ctl_frontend_offline(fe); } return (0); } /* * Returns 0 for success, 1 for failure. * Currently the only failure mode is if there aren't enough entries * allocated. So, in case of a failure, look at num_entries_dropped, * reallocate and try again. */ int ctl_port_list(struct ctl_port_entry *entries, int num_entries_alloced, int *num_entries_filled, int *num_entries_dropped, ctl_port_type port_type, int no_virtual) { struct ctl_softc *softc; struct ctl_frontend *fe; int entries_dropped, entries_filled; int retval; int i; softc = control_softc; retval = 0; entries_filled = 0; entries_dropped = 0; i = 0; mtx_lock(&softc->ctl_lock); STAILQ_FOREACH(fe, &softc->fe_list, links) { struct ctl_port_entry *entry; if ((fe->port_type & port_type) == 0) continue; if ((no_virtual != 0) && (fe->virtual_port != 0)) continue; if (entries_filled >= num_entries_alloced) { entries_dropped++; continue; } entry = &entries[i]; entry->port_type = fe->port_type; strlcpy(entry->port_name, fe->port_name, sizeof(entry->port_name)); entry->physical_port = fe->physical_port; entry->virtual_port = fe->virtual_port; entry->wwnn = fe->wwnn; entry->wwpn = fe->wwpn; i++; entries_filled++; } mtx_unlock(&softc->ctl_lock); if (entries_dropped > 0) retval = 1; *num_entries_dropped = entries_dropped; *num_entries_filled = entries_filled; return (retval); } static void ctl_ioctl_online(void *arg) { struct ctl_ioctl_info *ioctl_info; ioctl_info = (struct ctl_ioctl_info *)arg; ioctl_info->flags |= CTL_IOCTL_FLAG_ENABLED; } static void ctl_ioctl_offline(void *arg) { struct ctl_ioctl_info *ioctl_info; ioctl_info = (struct ctl_ioctl_info *)arg; ioctl_info->flags &= ~CTL_IOCTL_FLAG_ENABLED; } /* * Remove an initiator by port number and initiator ID. * Returns 0 for success, 1 for failure. * Assumes the caller does NOT hold the CTL lock. */ int ctl_remove_initiator(int32_t targ_port, uint32_t iid) { struct ctl_softc *softc; softc = control_softc; if ((targ_port < 0) || (targ_port > CTL_MAX_PORTS)) { printf("%s: invalid port number %d\n", __func__, targ_port); return (1); } if (iid > CTL_MAX_INIT_PER_PORT) { printf("%s: initiator ID %u > maximun %u!\n", __func__, iid, CTL_MAX_INIT_PER_PORT); return (1); } mtx_lock(&softc->ctl_lock); softc->wwpn_iid[targ_port][iid].in_use = 0; mtx_unlock(&softc->ctl_lock); return (0); } /* * Add an initiator to the initiator map. * Returns 0 for success, 1 for failure. * Assumes the caller does NOT hold the CTL lock. */ int ctl_add_initiator(uint64_t wwpn, int32_t targ_port, uint32_t iid) { struct ctl_softc *softc; int retval; softc = control_softc; retval = 0; if ((targ_port < 0) || (targ_port > CTL_MAX_PORTS)) { printf("%s: invalid port number %d\n", __func__, targ_port); return (1); } if (iid > CTL_MAX_INIT_PER_PORT) { printf("%s: WWPN %#jx initiator ID %u > maximun %u!\n", __func__, wwpn, iid, CTL_MAX_INIT_PER_PORT); return (1); } mtx_lock(&softc->ctl_lock); if (softc->wwpn_iid[targ_port][iid].in_use != 0) { /* * We don't treat this as an error. */ if (softc->wwpn_iid[targ_port][iid].wwpn == wwpn) { printf("%s: port %d iid %u WWPN %#jx arrived again?\n", __func__, targ_port, iid, (uintmax_t)wwpn); goto bailout; } /* * This is an error, but what do we do about it? The * driver is telling us we have a new WWPN for this * initiator ID, so we pretty much need to use it. */ printf("%s: port %d iid %u WWPN %#jx arrived, WWPN %#jx is " "still at that address\n", __func__, targ_port, iid, (uintmax_t)wwpn, (uintmax_t)softc->wwpn_iid[targ_port][iid].wwpn); /* * XXX KDM clear have_ca and ua_pending on each LUN for * this initiator. */ } softc->wwpn_iid[targ_port][iid].in_use = 1; softc->wwpn_iid[targ_port][iid].iid = iid; softc->wwpn_iid[targ_port][iid].wwpn = wwpn; softc->wwpn_iid[targ_port][iid].port = targ_port; bailout: mtx_unlock(&softc->ctl_lock); return (retval); } /* * XXX KDM should we pretend to do something in the target/lun * enable/disable functions? */ static int ctl_ioctl_targ_enable(void *arg, struct ctl_id targ_id) { return (0); } static int ctl_ioctl_targ_disable(void *arg, struct ctl_id targ_id) { return (0); } static int ctl_ioctl_lun_enable(void *arg, struct ctl_id targ_id, int lun_id) { return (0); } static int ctl_ioctl_lun_disable(void *arg, struct ctl_id targ_id, int lun_id) { return (0); } /* * Data movement routine for the CTL ioctl frontend port. */ static int ctl_ioctl_do_datamove(struct ctl_scsiio *ctsio) { struct ctl_sg_entry *ext_sglist, *kern_sglist; struct ctl_sg_entry ext_entry, kern_entry; int ext_sglen, ext_sg_entries, kern_sg_entries; int ext_sg_start, ext_offset; int len_to_copy, len_copied; int kern_watermark, ext_watermark; int ext_sglist_malloced; int i, j; ext_sglist_malloced = 0; ext_sg_start = 0; ext_offset = 0; CTL_DEBUG_PRINT(("ctl_ioctl_do_datamove\n")); /* * If this flag is set, fake the data transfer. */ if (ctsio->io_hdr.flags & CTL_FLAG_NO_DATAMOVE) { ctsio->ext_data_filled = ctsio->ext_data_len; goto bailout; } /* * To simplify things here, if we have a single buffer, stick it in * a S/G entry and just make it a single entry S/G list. */ if (ctsio->io_hdr.flags & CTL_FLAG_EDPTR_SGLIST) { int len_seen; ext_sglen = ctsio->ext_sg_entries * sizeof(*ext_sglist); ext_sglist = (struct ctl_sg_entry *)malloc(ext_sglen, M_CTL, M_WAITOK); if (ext_sglist == NULL) { ctl_set_internal_failure(ctsio, /*sks_valid*/ 0, /*retry_count*/ 0); return (CTL_RETVAL_COMPLETE); } ext_sglist_malloced = 1; if (copyin(ctsio->ext_data_ptr, ext_sglist, ext_sglen) != 0) { ctl_set_internal_failure(ctsio, /*sks_valid*/ 0, /*retry_count*/ 0); goto bailout; } ext_sg_entries = ctsio->ext_sg_entries; len_seen = 0; for (i = 0; i < ext_sg_entries; i++) { if ((len_seen + ext_sglist[i].len) >= ctsio->ext_data_filled) { ext_sg_start = i; ext_offset = ctsio->ext_data_filled - len_seen; break; } len_seen += ext_sglist[i].len; } } else { ext_sglist = &ext_entry; ext_sglist->addr = ctsio->ext_data_ptr; ext_sglist->len = ctsio->ext_data_len; ext_sg_entries = 1; ext_sg_start = 0; ext_offset = ctsio->ext_data_filled; } if (ctsio->kern_sg_entries > 0) { kern_sglist = (struct ctl_sg_entry *)ctsio->kern_data_ptr; kern_sg_entries = ctsio->kern_sg_entries; } else { kern_sglist = &kern_entry; kern_sglist->addr = ctsio->kern_data_ptr; kern_sglist->len = ctsio->kern_data_len; kern_sg_entries = 1; } kern_watermark = 0; ext_watermark = ext_offset; len_copied = 0; for (i = ext_sg_start, j = 0; i < ext_sg_entries && j < kern_sg_entries;) { uint8_t *ext_ptr, *kern_ptr; len_to_copy = ctl_min(ext_sglist[i].len - ext_watermark, kern_sglist[j].len - kern_watermark); ext_ptr = (uint8_t *)ext_sglist[i].addr; ext_ptr = ext_ptr + ext_watermark; if (ctsio->io_hdr.flags & CTL_FLAG_BUS_ADDR) { /* * XXX KDM fix this! */ panic("need to implement bus address support"); #if 0 kern_ptr = bus_to_virt(kern_sglist[j].addr); #endif } else kern_ptr = (uint8_t *)kern_sglist[j].addr; kern_ptr = kern_ptr + kern_watermark; kern_watermark += len_to_copy; ext_watermark += len_to_copy; if ((ctsio->io_hdr.flags & CTL_FLAG_DATA_MASK) == CTL_FLAG_DATA_IN) { CTL_DEBUG_PRINT(("ctl_ioctl_do_datamove: copying %d " "bytes to user\n", len_to_copy)); CTL_DEBUG_PRINT(("ctl_ioctl_do_datamove: from %p " "to %p\n", kern_ptr, ext_ptr)); if (copyout(kern_ptr, ext_ptr, len_to_copy) != 0) { ctl_set_internal_failure(ctsio, /*sks_valid*/ 0, /*retry_count*/ 0); goto bailout; } } else { CTL_DEBUG_PRINT(("ctl_ioctl_do_datamove: copying %d " "bytes from user\n", len_to_copy)); CTL_DEBUG_PRINT(("ctl_ioctl_do_datamove: from %p " "to %p\n", ext_ptr, kern_ptr)); if (copyin(ext_ptr, kern_ptr, len_to_copy)!= 0){ ctl_set_internal_failure(ctsio, /*sks_valid*/ 0, /*retry_count*/0); goto bailout; } } len_copied += len_to_copy; if (ext_sglist[i].len == ext_watermark) { i++; ext_watermark = 0; } if (kern_sglist[j].len == kern_watermark) { j++; kern_watermark = 0; } } ctsio->ext_data_filled += len_copied; CTL_DEBUG_PRINT(("ctl_ioctl_do_datamove: ext_sg_entries: %d, " "kern_sg_entries: %d\n", ext_sg_entries, kern_sg_entries)); CTL_DEBUG_PRINT(("ctl_ioctl_do_datamove: ext_data_len = %d, " "kern_data_len = %d\n", ctsio->ext_data_len, ctsio->kern_data_len)); /* XXX KDM set residual?? */ bailout: if (ext_sglist_malloced != 0) free(ext_sglist, M_CTL); return (CTL_RETVAL_COMPLETE); } /* * Serialize a command that went down the "wrong" side, and so was sent to * this controller for execution. The logic is a little different than the * standard case in ctl_scsiio_precheck(). Errors in this case need to get * sent back to the other side, but in the success case, we execute the * command on this side (XFER mode) or tell the other side to execute it * (SER_ONLY mode). */ static int ctl_serialize_other_sc_cmd(struct ctl_scsiio *ctsio, int have_lock) { struct ctl_softc *ctl_softc; union ctl_ha_msg msg_info; struct ctl_lun *lun; int retval = 0; ctl_softc = control_softc; if (have_lock == 0) mtx_lock(&ctl_softc->ctl_lock); lun = ctl_softc->ctl_luns[ctsio->io_hdr.nexus.targ_lun]; if (lun==NULL) { /* * Why isn't LUN defined? The other side wouldn't * send a cmd if the LUN is undefined. */ printf("%s: Bad JUJU!, LUN is NULL!\n", __func__); /* "Logical unit not supported" */ ctl_set_sense_data(&msg_info.scsi.sense_data, lun, /*sense_format*/SSD_TYPE_NONE, /*current_error*/ 1, /*sense_key*/ SSD_KEY_ILLEGAL_REQUEST, /*asc*/ 0x25, /*ascq*/ 0x00, SSD_ELEM_NONE); msg_info.scsi.sense_len = SSD_FULL_SIZE; msg_info.scsi.scsi_status = SCSI_STATUS_CHECK_COND; msg_info.hdr.status = CTL_SCSI_ERROR | CTL_AUTOSENSE; msg_info.hdr.original_sc = ctsio->io_hdr.original_sc; msg_info.hdr.serializing_sc = NULL; msg_info.hdr.msg_type = CTL_MSG_BAD_JUJU; if (ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg_info, sizeof(msg_info), 0 ) > CTL_HA_STATUS_SUCCESS) { } if (have_lock == 0) mtx_unlock(&ctl_softc->ctl_lock); return(1); } TAILQ_INSERT_TAIL(&lun->ooa_queue, &ctsio->io_hdr, ooa_links); switch (ctl_check_ooa(lun, (union ctl_io *)ctsio, (union ctl_io *)TAILQ_PREV(&ctsio->io_hdr, ctl_ooaq, ooa_links))) { case CTL_ACTION_BLOCK: ctsio->io_hdr.flags |= CTL_FLAG_BLOCKED; TAILQ_INSERT_TAIL(&lun->blocked_queue, &ctsio->io_hdr, blocked_links); break; case CTL_ACTION_PASS: case CTL_ACTION_SKIP: if (ctl_softc->ha_mode == CTL_HA_MODE_XFER) { ctsio->io_hdr.flags |= CTL_FLAG_IS_WAS_ON_RTR; STAILQ_INSERT_TAIL(&ctl_softc->rtr_queue, &ctsio->io_hdr, links); } else { /* send msg back to other side */ msg_info.hdr.original_sc = ctsio->io_hdr.original_sc; msg_info.hdr.serializing_sc = (union ctl_io *)ctsio; msg_info.hdr.msg_type = CTL_MSG_R2R; #if 0 printf("2. pOrig %x\n", (int)msg_info.hdr.original_sc); #endif if (ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg_info, sizeof(msg_info), 0 ) > CTL_HA_STATUS_SUCCESS) { } } break; case CTL_ACTION_OVERLAP: /* OVERLAPPED COMMANDS ATTEMPTED */ ctl_set_sense_data(&msg_info.scsi.sense_data, lun, /*sense_format*/SSD_TYPE_NONE, /*current_error*/ 1, /*sense_key*/ SSD_KEY_ILLEGAL_REQUEST, /*asc*/ 0x4E, /*ascq*/ 0x00, SSD_ELEM_NONE); msg_info.scsi.sense_len = SSD_FULL_SIZE; msg_info.scsi.scsi_status = SCSI_STATUS_CHECK_COND; msg_info.hdr.status = CTL_SCSI_ERROR | CTL_AUTOSENSE; msg_info.hdr.original_sc = ctsio->io_hdr.original_sc; msg_info.hdr.serializing_sc = NULL; msg_info.hdr.msg_type = CTL_MSG_BAD_JUJU; #if 0 printf("BAD JUJU:Major Bummer Overlap\n"); #endif TAILQ_REMOVE(&lun->ooa_queue, &ctsio->io_hdr, ooa_links); retval = 1; if (ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg_info, sizeof(msg_info), 0 ) > CTL_HA_STATUS_SUCCESS) { } break; case CTL_ACTION_OVERLAP_TAG: /* TAGGED OVERLAPPED COMMANDS (NN = QUEUE TAG) */ ctl_set_sense_data(&msg_info.scsi.sense_data, lun, /*sense_format*/SSD_TYPE_NONE, /*current_error*/ 1, /*sense_key*/ SSD_KEY_ILLEGAL_REQUEST, /*asc*/ 0x4D, /*ascq*/ ctsio->tag_num & 0xff, SSD_ELEM_NONE); msg_info.scsi.sense_len = SSD_FULL_SIZE; msg_info.scsi.scsi_status = SCSI_STATUS_CHECK_COND; msg_info.hdr.status = CTL_SCSI_ERROR | CTL_AUTOSENSE; msg_info.hdr.original_sc = ctsio->io_hdr.original_sc; msg_info.hdr.serializing_sc = NULL; msg_info.hdr.msg_type = CTL_MSG_BAD_JUJU; #if 0 printf("BAD JUJU:Major Bummer Overlap Tag\n"); #endif TAILQ_REMOVE(&lun->ooa_queue, &ctsio->io_hdr, ooa_links); retval = 1; if (ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg_info, sizeof(msg_info), 0 ) > CTL_HA_STATUS_SUCCESS) { } break; case CTL_ACTION_ERROR: default: /* "Internal target failure" */ ctl_set_sense_data(&msg_info.scsi.sense_data, lun, /*sense_format*/SSD_TYPE_NONE, /*current_error*/ 1, /*sense_key*/ SSD_KEY_HARDWARE_ERROR, /*asc*/ 0x44, /*ascq*/ 0x00, SSD_ELEM_NONE); msg_info.scsi.sense_len = SSD_FULL_SIZE; msg_info.scsi.scsi_status = SCSI_STATUS_CHECK_COND; msg_info.hdr.status = CTL_SCSI_ERROR | CTL_AUTOSENSE; msg_info.hdr.original_sc = ctsio->io_hdr.original_sc; msg_info.hdr.serializing_sc = NULL; msg_info.hdr.msg_type = CTL_MSG_BAD_JUJU; #if 0 printf("BAD JUJU:Major Bummer HW Error\n"); #endif TAILQ_REMOVE(&lun->ooa_queue, &ctsio->io_hdr, ooa_links); retval = 1; if (ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg_info, sizeof(msg_info), 0 ) > CTL_HA_STATUS_SUCCESS) { } break; } if (have_lock == 0) mtx_unlock(&ctl_softc->ctl_lock); return (retval); } static int ctl_ioctl_submit_wait(union ctl_io *io) { struct ctl_fe_ioctl_params params; ctl_fe_ioctl_state last_state; int done, retval; retval = 0; bzero(¶ms, sizeof(params)); mtx_init(¶ms.ioctl_mtx, "ctliocmtx", NULL, MTX_DEF); cv_init(¶ms.sem, "ctlioccv"); params.state = CTL_IOCTL_INPROG; last_state = params.state; io->io_hdr.ctl_private[CTL_PRIV_FRONTEND].ptr = ¶ms; CTL_DEBUG_PRINT(("ctl_ioctl_submit_wait\n")); /* This shouldn't happen */ if ((retval = ctl_queue(io)) != CTL_RETVAL_COMPLETE) return (retval); done = 0; do { mtx_lock(¶ms.ioctl_mtx); /* * Check the state here, and don't sleep if the state has * already changed (i.e. wakeup has already occured, but we * weren't waiting yet). */ if (params.state == last_state) { /* XXX KDM cv_wait_sig instead? */ cv_wait(¶ms.sem, ¶ms.ioctl_mtx); } last_state = params.state; switch (params.state) { case CTL_IOCTL_INPROG: /* Why did we wake up? */ /* XXX KDM error here? */ mtx_unlock(¶ms.ioctl_mtx); break; case CTL_IOCTL_DATAMOVE: CTL_DEBUG_PRINT(("got CTL_IOCTL_DATAMOVE\n")); /* * change last_state back to INPROG to avoid * deadlock on subsequent data moves. */ params.state = last_state = CTL_IOCTL_INPROG; mtx_unlock(¶ms.ioctl_mtx); ctl_ioctl_do_datamove(&io->scsiio); /* * Note that in some cases, most notably writes, * this will queue the I/O and call us back later. * In other cases, generally reads, this routine * will immediately call back and wake us up, * probably using our own context. */ io->scsiio.be_move_done(io); break; case CTL_IOCTL_DONE: mtx_unlock(¶ms.ioctl_mtx); CTL_DEBUG_PRINT(("got CTL_IOCTL_DONE\n")); done = 1; break; default: mtx_unlock(¶ms.ioctl_mtx); /* XXX KDM error here? */ break; } } while (done == 0); mtx_destroy(¶ms.ioctl_mtx); cv_destroy(¶ms.sem); return (CTL_RETVAL_COMPLETE); } static void ctl_ioctl_datamove(union ctl_io *io) { struct ctl_fe_ioctl_params *params; params = (struct ctl_fe_ioctl_params *) io->io_hdr.ctl_private[CTL_PRIV_FRONTEND].ptr; mtx_lock(¶ms->ioctl_mtx); params->state = CTL_IOCTL_DATAMOVE; cv_broadcast(¶ms->sem); mtx_unlock(¶ms->ioctl_mtx); } static void ctl_ioctl_done(union ctl_io *io) { struct ctl_fe_ioctl_params *params; params = (struct ctl_fe_ioctl_params *) io->io_hdr.ctl_private[CTL_PRIV_FRONTEND].ptr; mtx_lock(¶ms->ioctl_mtx); params->state = CTL_IOCTL_DONE; cv_broadcast(¶ms->sem); mtx_unlock(¶ms->ioctl_mtx); } static void ctl_ioctl_hard_startstop_callback(void *arg, struct cfi_metatask *metatask) { struct ctl_fe_ioctl_startstop_info *sd_info; sd_info = (struct ctl_fe_ioctl_startstop_info *)arg; sd_info->hs_info.status = metatask->status; sd_info->hs_info.total_luns = metatask->taskinfo.startstop.total_luns; sd_info->hs_info.luns_complete = metatask->taskinfo.startstop.luns_complete; sd_info->hs_info.luns_failed = metatask->taskinfo.startstop.luns_failed; cv_broadcast(&sd_info->sem); } static void ctl_ioctl_bbrread_callback(void *arg, struct cfi_metatask *metatask) { struct ctl_fe_ioctl_bbrread_info *fe_bbr_info; fe_bbr_info = (struct ctl_fe_ioctl_bbrread_info *)arg; mtx_lock(fe_bbr_info->lock); fe_bbr_info->bbr_info->status = metatask->status; fe_bbr_info->bbr_info->bbr_status = metatask->taskinfo.bbrread.status; fe_bbr_info->wakeup_done = 1; mtx_unlock(fe_bbr_info->lock); cv_broadcast(&fe_bbr_info->sem); } /* * Must be called with the ctl_lock held. * Returns 0 for success, errno for failure. */ static int ctl_ioctl_fill_ooa(struct ctl_lun *lun, uint32_t *cur_fill_num, struct ctl_ooa *ooa_hdr) { union ctl_io *io; int retval; retval = 0; for (io = (union ctl_io *)TAILQ_FIRST(&lun->ooa_queue); (io != NULL); (*cur_fill_num)++, io = (union ctl_io *)TAILQ_NEXT(&io->io_hdr, ooa_links)) { struct ctl_ooa_entry *cur_entry, entry; /* * If we've got more than we can fit, just count the * remaining entries. */ if (*cur_fill_num >= ooa_hdr->alloc_num) continue; cur_entry = &ooa_hdr->entries[*cur_fill_num]; bzero(&entry, sizeof(entry)); entry.tag_num = io->scsiio.tag_num; entry.lun_num = lun->lun; #ifdef CTL_TIME_IO entry.start_bt = io->io_hdr.start_bt; #endif bcopy(io->scsiio.cdb, entry.cdb, io->scsiio.cdb_len); entry.cdb_len = io->scsiio.cdb_len; if (io->io_hdr.flags & CTL_FLAG_BLOCKED) entry.cmd_flags |= CTL_OOACMD_FLAG_BLOCKED; if (io->io_hdr.flags & CTL_FLAG_DMA_INPROG) entry.cmd_flags |= CTL_OOACMD_FLAG_DMA; if (io->io_hdr.flags & CTL_FLAG_ABORT) entry.cmd_flags |= CTL_OOACMD_FLAG_ABORT; if (io->io_hdr.flags & CTL_FLAG_IS_WAS_ON_RTR) entry.cmd_flags |= CTL_OOACMD_FLAG_RTR; if (io->io_hdr.flags & CTL_FLAG_DMA_QUEUED) entry.cmd_flags |= CTL_OOACMD_FLAG_DMA_QUEUED; retval = copyout(&entry, cur_entry, sizeof(entry)); if (retval != 0) break; } return (retval); } static void * ctl_copyin_alloc(void *user_addr, int len, char *error_str, size_t error_str_len) { void *kptr; kptr = malloc(len, M_CTL, M_WAITOK | M_ZERO); if (kptr == NULL) { snprintf(error_str, error_str_len, "Cannot allocate %d bytes", len); return (NULL); } if (copyin(user_addr, kptr, len) != 0) { snprintf(error_str, error_str_len, "Error copying %d bytes " "from user address %p to kernel address %p", len, user_addr, kptr); free(kptr, M_CTL); return (NULL); } return (kptr); } static void ctl_free_args(int num_be_args, struct ctl_be_arg *be_args) { int i; if (be_args == NULL) return; for (i = 0; i < num_be_args; i++) { free(be_args[i].kname, M_CTL); free(be_args[i].kvalue, M_CTL); } free(be_args, M_CTL); } static struct ctl_be_arg * ctl_copyin_args(int num_be_args, struct ctl_be_arg *be_args, char *error_str, size_t error_str_len) { struct ctl_be_arg *args; int i; args = ctl_copyin_alloc(be_args, num_be_args * sizeof(*be_args), error_str, error_str_len); if (args == NULL) goto bailout; for (i = 0; i < num_be_args; i++) { uint8_t *tmpptr; args[i].kname = ctl_copyin_alloc(args[i].name, args[i].namelen, error_str, error_str_len); if (args[i].kname == NULL) goto bailout; if (args[i].kname[args[i].namelen - 1] != '\0') { snprintf(error_str, error_str_len, "Argument %d " "name is not NUL-terminated", i); goto bailout; } args[i].kvalue = NULL; tmpptr = ctl_copyin_alloc(args[i].value, args[i].vallen, error_str, error_str_len); if (tmpptr == NULL) goto bailout; args[i].kvalue = tmpptr; if ((args[i].flags & CTL_BEARG_ASCII) && (tmpptr[args[i].vallen - 1] != '\0')) { snprintf(error_str, error_str_len, "Argument %d " "value is not NUL-terminated", i); goto bailout; } } return (args); bailout: ctl_free_args(num_be_args, args); return (NULL); } /* * Escape characters that are illegal or not recommended in XML. */ int ctl_sbuf_printf_esc(struct sbuf *sb, char *str) { int retval; retval = 0; for (; *str; str++) { switch (*str) { case '&': retval = sbuf_printf(sb, "&"); break; case '>': retval = sbuf_printf(sb, ">"); break; case '<': retval = sbuf_printf(sb, "<"); break; default: retval = sbuf_putc(sb, *str); break; } if (retval != 0) break; } return (retval); } static int ctl_ioctl(struct cdev *dev, u_long cmd, caddr_t addr, int flag, struct thread *td) { struct ctl_softc *softc; int retval; softc = control_softc; retval = 0; switch (cmd) { case CTL_IO: { union ctl_io *io; void *pool_tmp; /* * If we haven't been "enabled", don't allow any SCSI I/O * to this FETD. */ if ((softc->ioctl_info.flags & CTL_IOCTL_FLAG_ENABLED) == 0) { retval = -EPERM; break; } io = ctl_alloc_io(softc->ioctl_info.fe.ctl_pool_ref); if (io == NULL) { printf("ctl_ioctl: can't allocate ctl_io!\n"); retval = -ENOSPC; break; } /* * Need to save the pool reference so it doesn't get * spammed by the user's ctl_io. */ pool_tmp = io->io_hdr.pool; memcpy(io, (void *)addr, sizeof(*io)); io->io_hdr.pool = pool_tmp; /* * No status yet, so make sure the status is set properly. */ io->io_hdr.status = CTL_STATUS_NONE; /* * The user sets the initiator ID, target and LUN IDs. */ io->io_hdr.nexus.targ_port = softc->ioctl_info.fe.targ_port; io->io_hdr.flags |= CTL_FLAG_USER_REQ; if ((io->io_hdr.io_type == CTL_IO_SCSI) && (io->scsiio.tag_type != CTL_TAG_UNTAGGED)) io->scsiio.tag_num = softc->ioctl_info.cur_tag_num++; retval = ctl_ioctl_submit_wait(io); if (retval != 0) { ctl_free_io(io); break; } memcpy((void *)addr, io, sizeof(*io)); /* return this to our pool */ ctl_free_io(io); break; } case CTL_ENABLE_PORT: case CTL_DISABLE_PORT: case CTL_SET_PORT_WWNS: { struct ctl_frontend *fe; struct ctl_port_entry *entry; entry = (struct ctl_port_entry *)addr; mtx_lock(&softc->ctl_lock); STAILQ_FOREACH(fe, &softc->fe_list, links) { int action, done; action = 0; done = 0; if ((entry->port_type == CTL_PORT_NONE) && (entry->targ_port == fe->targ_port)) { /* * If the user only wants to enable or * disable or set WWNs on a specific port, * do the operation and we're done. */ action = 1; done = 1; } else if (entry->port_type & fe->port_type) { /* * Compare the user's type mask with the * particular frontend type to see if we * have a match. */ action = 1; done = 0; /* * Make sure the user isn't trying to set * WWNs on multiple ports at the same time. */ if (cmd == CTL_SET_PORT_WWNS) { printf("%s: Can't set WWNs on " "multiple ports\n", __func__); retval = EINVAL; break; } } if (action != 0) { /* * XXX KDM we have to drop the lock here, * because the online/offline operations * can potentially block. We need to * reference count the frontends so they * can't go away, */ mtx_unlock(&softc->ctl_lock); if (cmd == CTL_ENABLE_PORT) ctl_frontend_online(fe); else if (cmd == CTL_DISABLE_PORT) ctl_frontend_offline(fe); mtx_lock(&softc->ctl_lock); if (cmd == CTL_SET_PORT_WWNS) ctl_frontend_set_wwns(fe, (entry->flags & CTL_PORT_WWNN_VALID) ? 1 : 0, entry->wwnn, (entry->flags & CTL_PORT_WWPN_VALID) ? 1 : 0, entry->wwpn); } if (done != 0) break; } mtx_unlock(&softc->ctl_lock); break; } case CTL_GET_PORT_LIST: { struct ctl_frontend *fe; struct ctl_port_list *list; int i; list = (struct ctl_port_list *)addr; if (list->alloc_len != (list->alloc_num * sizeof(struct ctl_port_entry))) { printf("%s: CTL_GET_PORT_LIST: alloc_len %u != " "alloc_num %u * sizeof(struct ctl_port_entry) " "%zu\n", __func__, list->alloc_len, list->alloc_num, sizeof(struct ctl_port_entry)); retval = EINVAL; break; } list->fill_len = 0; list->fill_num = 0; list->dropped_num = 0; i = 0; mtx_lock(&softc->ctl_lock); STAILQ_FOREACH(fe, &softc->fe_list, links) { struct ctl_port_entry entry, *list_entry; if (list->fill_num >= list->alloc_num) { list->dropped_num++; continue; } entry.port_type = fe->port_type; strlcpy(entry.port_name, fe->port_name, sizeof(entry.port_name)); entry.targ_port = fe->targ_port; entry.physical_port = fe->physical_port; entry.virtual_port = fe->virtual_port; entry.wwnn = fe->wwnn; entry.wwpn = fe->wwpn; if (fe->status & CTL_PORT_STATUS_ONLINE) entry.online = 1; else entry.online = 0; list_entry = &list->entries[i]; retval = copyout(&entry, list_entry, sizeof(entry)); if (retval != 0) { printf("%s: CTL_GET_PORT_LIST: copyout " "returned %d\n", __func__, retval); break; } i++; list->fill_num++; list->fill_len += sizeof(entry); } mtx_unlock(&softc->ctl_lock); /* * If this is non-zero, we had a copyout fault, so there's * probably no point in attempting to set the status inside * the structure. */ if (retval != 0) break; if (list->dropped_num > 0) list->status = CTL_PORT_LIST_NEED_MORE_SPACE; else list->status = CTL_PORT_LIST_OK; break; } case CTL_DUMP_OOA: { struct ctl_lun *lun; union ctl_io *io; char printbuf[128]; struct sbuf sb; mtx_lock(&softc->ctl_lock); printf("Dumping OOA queues:\n"); STAILQ_FOREACH(lun, &softc->lun_list, links) { for (io = (union ctl_io *)TAILQ_FIRST( &lun->ooa_queue); io != NULL; io = (union ctl_io *)TAILQ_NEXT(&io->io_hdr, ooa_links)) { sbuf_new(&sb, printbuf, sizeof(printbuf), SBUF_FIXEDLEN); sbuf_printf(&sb, "LUN %jd tag 0x%04x%s%s%s%s: ", (intmax_t)lun->lun, io->scsiio.tag_num, (io->io_hdr.flags & CTL_FLAG_BLOCKED) ? "" : " BLOCKED", (io->io_hdr.flags & CTL_FLAG_DMA_INPROG) ? " DMA" : "", (io->io_hdr.flags & CTL_FLAG_ABORT) ? " ABORT" : "", (io->io_hdr.flags & CTL_FLAG_IS_WAS_ON_RTR) ? " RTR" : ""); ctl_scsi_command_string(&io->scsiio, NULL, &sb); sbuf_finish(&sb); printf("%s\n", sbuf_data(&sb)); } } printf("OOA queues dump done\n"); mtx_unlock(&softc->ctl_lock); break; } case CTL_GET_OOA: { struct ctl_lun *lun; struct ctl_ooa *ooa_hdr; uint32_t cur_fill_num; ooa_hdr = (struct ctl_ooa *)addr; if ((ooa_hdr->alloc_len == 0) || (ooa_hdr->alloc_num == 0)) { printf("%s: CTL_GET_OOA: alloc len %u and alloc num %u " "must be non-zero\n", __func__, ooa_hdr->alloc_len, ooa_hdr->alloc_num); retval = EINVAL; break; } if (ooa_hdr->alloc_len != (ooa_hdr->alloc_num * sizeof(struct ctl_ooa_entry))) { printf("%s: CTL_GET_OOA: alloc len %u must be alloc " "num %d * sizeof(struct ctl_ooa_entry) %zd\n", __func__, ooa_hdr->alloc_len, ooa_hdr->alloc_num,sizeof(struct ctl_ooa_entry)); retval = EINVAL; break; } mtx_lock(&softc->ctl_lock); if (((ooa_hdr->flags & CTL_OOA_FLAG_ALL_LUNS) == 0) && ((ooa_hdr->lun_num > CTL_MAX_LUNS) || (softc->ctl_luns[ooa_hdr->lun_num] == NULL))) { mtx_unlock(&softc->ctl_lock); printf("%s: CTL_GET_OOA: invalid LUN %ju\n", __func__, (uintmax_t)ooa_hdr->lun_num); retval = EINVAL; break; } cur_fill_num = 0; if (ooa_hdr->flags & CTL_OOA_FLAG_ALL_LUNS) { STAILQ_FOREACH(lun, &softc->lun_list, links) { retval = ctl_ioctl_fill_ooa(lun, &cur_fill_num, ooa_hdr); if (retval != 0) break; } if (retval != 0) { mtx_unlock(&softc->ctl_lock); break; } } else { lun = softc->ctl_luns[ooa_hdr->lun_num]; retval = ctl_ioctl_fill_ooa(lun, &cur_fill_num,ooa_hdr); } mtx_unlock(&softc->ctl_lock); ooa_hdr->fill_num = min(cur_fill_num, ooa_hdr->alloc_num); ooa_hdr->fill_len = ooa_hdr->fill_num * sizeof(struct ctl_ooa_entry); getbintime(&ooa_hdr->cur_bt); if (cur_fill_num > ooa_hdr->alloc_num) { ooa_hdr->dropped_num = cur_fill_num -ooa_hdr->alloc_num; ooa_hdr->status = CTL_OOA_NEED_MORE_SPACE; } else { ooa_hdr->dropped_num = 0; ooa_hdr->status = CTL_OOA_OK; } break; } case CTL_CHECK_OOA: { union ctl_io *io; struct ctl_lun *lun; struct ctl_ooa_info *ooa_info; ooa_info = (struct ctl_ooa_info *)addr; if (ooa_info->lun_id >= CTL_MAX_LUNS) { ooa_info->status = CTL_OOA_INVALID_LUN; break; } mtx_lock(&softc->ctl_lock); lun = softc->ctl_luns[ooa_info->lun_id]; if (lun == NULL) { mtx_unlock(&softc->ctl_lock); ooa_info->status = CTL_OOA_INVALID_LUN; break; } ooa_info->num_entries = 0; for (io = (union ctl_io *)TAILQ_FIRST(&lun->ooa_queue); io != NULL; io = (union ctl_io *)TAILQ_NEXT( &io->io_hdr, ooa_links)) { ooa_info->num_entries++; } mtx_unlock(&softc->ctl_lock); ooa_info->status = CTL_OOA_SUCCESS; break; } case CTL_HARD_START: case CTL_HARD_STOP: { struct ctl_fe_ioctl_startstop_info ss_info; struct cfi_metatask *metatask; struct mtx hs_mtx; mtx_init(&hs_mtx, "HS Mutex", NULL, MTX_DEF); cv_init(&ss_info.sem, "hard start/stop cv" ); metatask = cfi_alloc_metatask(/*can_wait*/ 1); if (metatask == NULL) { retval = ENOMEM; mtx_destroy(&hs_mtx); break; } if (cmd == CTL_HARD_START) metatask->tasktype = CFI_TASK_STARTUP; else metatask->tasktype = CFI_TASK_SHUTDOWN; metatask->callback = ctl_ioctl_hard_startstop_callback; metatask->callback_arg = &ss_info; cfi_action(metatask); /* Wait for the callback */ mtx_lock(&hs_mtx); cv_wait_sig(&ss_info.sem, &hs_mtx); mtx_unlock(&hs_mtx); /* * All information has been copied from the metatask by the * time cv_broadcast() is called, so we free the metatask here. */ cfi_free_metatask(metatask); memcpy((void *)addr, &ss_info.hs_info, sizeof(ss_info.hs_info)); mtx_destroy(&hs_mtx); break; } case CTL_BBRREAD: { struct ctl_bbrread_info *bbr_info; struct ctl_fe_ioctl_bbrread_info fe_bbr_info; struct mtx bbr_mtx; struct cfi_metatask *metatask; bbr_info = (struct ctl_bbrread_info *)addr; bzero(&fe_bbr_info, sizeof(fe_bbr_info)); bzero(&bbr_mtx, sizeof(bbr_mtx)); mtx_init(&bbr_mtx, "BBR Mutex", NULL, MTX_DEF); fe_bbr_info.bbr_info = bbr_info; fe_bbr_info.lock = &bbr_mtx; cv_init(&fe_bbr_info.sem, "BBR read cv"); metatask = cfi_alloc_metatask(/*can_wait*/ 1); if (metatask == NULL) { mtx_destroy(&bbr_mtx); cv_destroy(&fe_bbr_info.sem); retval = ENOMEM; break; } metatask->tasktype = CFI_TASK_BBRREAD; metatask->callback = ctl_ioctl_bbrread_callback; metatask->callback_arg = &fe_bbr_info; metatask->taskinfo.bbrread.lun_num = bbr_info->lun_num; metatask->taskinfo.bbrread.lba = bbr_info->lba; metatask->taskinfo.bbrread.len = bbr_info->len; cfi_action(metatask); mtx_lock(&bbr_mtx); while (fe_bbr_info.wakeup_done == 0) cv_wait_sig(&fe_bbr_info.sem, &bbr_mtx); mtx_unlock(&bbr_mtx); bbr_info->status = metatask->status; bbr_info->bbr_status = metatask->taskinfo.bbrread.status; bbr_info->scsi_status = metatask->taskinfo.bbrread.scsi_status; memcpy(&bbr_info->sense_data, &metatask->taskinfo.bbrread.sense_data, ctl_min(sizeof(bbr_info->sense_data), sizeof(metatask->taskinfo.bbrread.sense_data))); cfi_free_metatask(metatask); mtx_destroy(&bbr_mtx); cv_destroy(&fe_bbr_info.sem); break; } case CTL_DELAY_IO: { struct ctl_io_delay_info *delay_info; #ifdef CTL_IO_DELAY struct ctl_lun *lun; #endif /* CTL_IO_DELAY */ delay_info = (struct ctl_io_delay_info *)addr; #ifdef CTL_IO_DELAY mtx_lock(&softc->ctl_lock); if ((delay_info->lun_id > CTL_MAX_LUNS) || (softc->ctl_luns[delay_info->lun_id] == NULL)) { delay_info->status = CTL_DELAY_STATUS_INVALID_LUN; } else { lun = softc->ctl_luns[delay_info->lun_id]; delay_info->status = CTL_DELAY_STATUS_OK; switch (delay_info->delay_type) { case CTL_DELAY_TYPE_CONT: break; case CTL_DELAY_TYPE_ONESHOT: break; default: delay_info->status = CTL_DELAY_STATUS_INVALID_TYPE; break; } switch (delay_info->delay_loc) { case CTL_DELAY_LOC_DATAMOVE: lun->delay_info.datamove_type = delay_info->delay_type; lun->delay_info.datamove_delay = delay_info->delay_secs; break; case CTL_DELAY_LOC_DONE: lun->delay_info.done_type = delay_info->delay_type; lun->delay_info.done_delay = delay_info->delay_secs; break; default: delay_info->status = CTL_DELAY_STATUS_INVALID_LOC; break; } } mtx_unlock(&softc->ctl_lock); #else delay_info->status = CTL_DELAY_STATUS_NOT_IMPLEMENTED; #endif /* CTL_IO_DELAY */ break; } case CTL_REALSYNC_SET: { int *syncstate; syncstate = (int *)addr; mtx_lock(&softc->ctl_lock); switch (*syncstate) { case 0: softc->flags &= ~CTL_FLAG_REAL_SYNC; break; case 1: softc->flags |= CTL_FLAG_REAL_SYNC; break; default: retval = -EINVAL; break; } mtx_unlock(&softc->ctl_lock); break; } case CTL_REALSYNC_GET: { int *syncstate; syncstate = (int*)addr; mtx_lock(&softc->ctl_lock); if (softc->flags & CTL_FLAG_REAL_SYNC) *syncstate = 1; else *syncstate = 0; mtx_unlock(&softc->ctl_lock); break; } case CTL_SETSYNC: case CTL_GETSYNC: { struct ctl_sync_info *sync_info; struct ctl_lun *lun; sync_info = (struct ctl_sync_info *)addr; mtx_lock(&softc->ctl_lock); lun = softc->ctl_luns[sync_info->lun_id]; if (lun == NULL) { mtx_unlock(&softc->ctl_lock); sync_info->status = CTL_GS_SYNC_NO_LUN; } /* * Get or set the sync interval. We're not bounds checking * in the set case, hopefully the user won't do something * silly. */ if (cmd == CTL_GETSYNC) sync_info->sync_interval = lun->sync_interval; else lun->sync_interval = sync_info->sync_interval; mtx_unlock(&softc->ctl_lock); sync_info->status = CTL_GS_SYNC_OK; break; } case CTL_GETSTATS: { struct ctl_stats *stats; struct ctl_lun *lun; int i; stats = (struct ctl_stats *)addr; if ((sizeof(struct ctl_lun_io_stats) * softc->num_luns) > stats->alloc_len) { stats->status = CTL_SS_NEED_MORE_SPACE; stats->num_luns = softc->num_luns; break; } /* * XXX KDM no locking here. If the LUN list changes, * things can blow up. */ for (i = 0, lun = STAILQ_FIRST(&softc->lun_list); lun != NULL; i++, lun = STAILQ_NEXT(lun, links)) { retval = copyout(&lun->stats, &stats->lun_stats[i], sizeof(lun->stats)); if (retval != 0) break; } stats->num_luns = softc->num_luns; stats->fill_len = sizeof(struct ctl_lun_io_stats) * softc->num_luns; stats->status = CTL_SS_OK; #ifdef CTL_TIME_IO stats->flags = CTL_STATS_FLAG_TIME_VALID; #else stats->flags = CTL_STATS_FLAG_NONE; #endif getnanouptime(&stats->timestamp); break; } case CTL_ERROR_INJECT: { struct ctl_error_desc *err_desc, *new_err_desc; struct ctl_lun *lun; err_desc = (struct ctl_error_desc *)addr; new_err_desc = malloc(sizeof(*new_err_desc), M_CTL, M_WAITOK | M_ZERO); if (new_err_desc == NULL) { printf("%s: CTL_ERROR_INJECT: error allocating %zu " "bytes\n", __func__, sizeof(*new_err_desc)); retval = ENOMEM; break; } bcopy(err_desc, new_err_desc, sizeof(*new_err_desc)); mtx_lock(&softc->ctl_lock); lun = softc->ctl_luns[err_desc->lun_id]; if (lun == NULL) { mtx_unlock(&softc->ctl_lock); printf("%s: CTL_ERROR_INJECT: invalid LUN %ju\n", __func__, (uintmax_t)err_desc->lun_id); retval = EINVAL; break; } /* * We could do some checking here to verify the validity * of the request, but given the complexity of error * injection requests, the checking logic would be fairly * complex. * * For now, if the request is invalid, it just won't get * executed and might get deleted. */ STAILQ_INSERT_TAIL(&lun->error_list, new_err_desc, links); /* * XXX KDM check to make sure the serial number is unique, * in case we somehow manage to wrap. That shouldn't * happen for a very long time, but it's the right thing to * do. */ new_err_desc->serial = lun->error_serial; err_desc->serial = lun->error_serial; lun->error_serial++; mtx_unlock(&softc->ctl_lock); break; } case CTL_ERROR_INJECT_DELETE: { struct ctl_error_desc *delete_desc, *desc, *desc2; struct ctl_lun *lun; int delete_done; delete_desc = (struct ctl_error_desc *)addr; delete_done = 0; mtx_lock(&softc->ctl_lock); lun = softc->ctl_luns[delete_desc->lun_id]; if (lun == NULL) { mtx_unlock(&softc->ctl_lock); printf("%s: CTL_ERROR_INJECT_DELETE: invalid LUN %ju\n", __func__, (uintmax_t)delete_desc->lun_id); retval = EINVAL; break; } STAILQ_FOREACH_SAFE(desc, &lun->error_list, links, desc2) { if (desc->serial != delete_desc->serial) continue; STAILQ_REMOVE(&lun->error_list, desc, ctl_error_desc, links); free(desc, M_CTL); delete_done = 1; } mtx_unlock(&softc->ctl_lock); if (delete_done == 0) { printf("%s: CTL_ERROR_INJECT_DELETE: can't find " "error serial %ju on LUN %u\n", __func__, delete_desc->serial, delete_desc->lun_id); retval = EINVAL; break; } break; } case CTL_DUMP_STRUCTS: { int i, j, k; struct ctl_frontend *fe; printf("CTL IID to WWPN map start:\n"); for (i = 0; i < CTL_MAX_PORTS; i++) { for (j = 0; j < CTL_MAX_INIT_PER_PORT; j++) { if (softc->wwpn_iid[i][j].in_use == 0) continue; printf("port %d iid %u WWPN %#jx\n", softc->wwpn_iid[i][j].port, softc->wwpn_iid[i][j].iid, (uintmax_t)softc->wwpn_iid[i][j].wwpn); } } printf("CTL IID to WWPN map end\n"); printf("CTL Persistent Reservation information start:\n"); for (i = 0; i < CTL_MAX_LUNS; i++) { struct ctl_lun *lun; lun = softc->ctl_luns[i]; if ((lun == NULL) || ((lun->flags & CTL_LUN_DISABLED) != 0)) continue; for (j = 0; j < (CTL_MAX_PORTS * 2); j++) { for (k = 0; k < CTL_MAX_INIT_PER_PORT; k++){ if (lun->per_res[j+k].registered == 0) continue; printf("LUN %d port %d iid %d key " "%#jx\n", i, j, k, (uintmax_t)scsi_8btou64( lun->per_res[j+k].res_key.key)); } } } printf("CTL Persistent Reservation information end\n"); printf("CTL Frontends:\n"); /* * XXX KDM calling this without a lock. We'd likely want * to drop the lock before calling the frontend's dump * routine anyway. */ STAILQ_FOREACH(fe, &softc->fe_list, links) { printf("Frontend %s Type %u pport %d vport %d WWNN " "%#jx WWPN %#jx\n", fe->port_name, fe->port_type, fe->physical_port, fe->virtual_port, (uintmax_t)fe->wwnn, (uintmax_t)fe->wwpn); /* * Frontends are not required to support the dump * routine. */ if (fe->fe_dump == NULL) continue; fe->fe_dump(); } printf("CTL Frontend information end\n"); break; } case CTL_LUN_REQ: { struct ctl_lun_req *lun_req; struct ctl_backend_driver *backend; lun_req = (struct ctl_lun_req *)addr; backend = ctl_backend_find(lun_req->backend); if (backend == NULL) { lun_req->status = CTL_LUN_ERROR; snprintf(lun_req->error_str, sizeof(lun_req->error_str), "Backend \"%s\" not found.", lun_req->backend); break; } if (lun_req->num_be_args > 0) { lun_req->kern_be_args = ctl_copyin_args( lun_req->num_be_args, lun_req->be_args, lun_req->error_str, sizeof(lun_req->error_str)); if (lun_req->kern_be_args == NULL) { lun_req->status = CTL_LUN_ERROR; break; } } retval = backend->ioctl(dev, cmd, addr, flag, td); if (lun_req->num_be_args > 0) { ctl_free_args(lun_req->num_be_args, lun_req->kern_be_args); } break; } case CTL_LUN_LIST: { struct sbuf *sb; struct ctl_lun *lun; struct ctl_lun_list *list; list = (struct ctl_lun_list *)addr; /* * Allocate a fixed length sbuf here, based on the length * of the user's buffer. We could allocate an auto-extending * buffer, and then tell the user how much larger our * amount of data is than his buffer, but that presents * some problems: * * 1. The sbuf(9) routines use a blocking malloc, and so * we can't hold a lock while calling them with an * auto-extending buffer. * * 2. There is not currently a LUN reference counting * mechanism, outside of outstanding transactions on * the LUN's OOA queue. So a LUN could go away on us * while we're getting the LUN number, backend-specific * information, etc. Thus, given the way things * currently work, we need to hold the CTL lock while * grabbing LUN information. * * So, from the user's standpoint, the best thing to do is * allocate what he thinks is a reasonable buffer length, * and then if he gets a CTL_LUN_LIST_NEED_MORE_SPACE error, * double the buffer length and try again. (And repeat * that until he succeeds.) */ sb = sbuf_new(NULL, NULL, list->alloc_len, SBUF_FIXEDLEN); if (sb == NULL) { list->status = CTL_LUN_LIST_ERROR; snprintf(list->error_str, sizeof(list->error_str), "Unable to allocate %d bytes for LUN list", list->alloc_len); break; } sbuf_printf(sb, "<ctllunlist>\n"); mtx_lock(&softc->ctl_lock); STAILQ_FOREACH(lun, &softc->lun_list, links) { retval = sbuf_printf(sb, "<lun id=\"%ju\">\n", (uintmax_t)lun->lun); /* * Bail out as soon as we see that we've overfilled * the buffer. */ if (retval != 0) break; retval = sbuf_printf(sb, "<backend_type>%s" "</backend_type>\n", (lun->backend == NULL) ? "none" : lun->backend->name); if (retval != 0) break; retval = sbuf_printf(sb, "<lun_type>%d</lun_type>\n", lun->be_lun->lun_type); if (retval != 0) break; if (lun->backend == NULL) { retval = sbuf_printf(sb, "</lun>\n"); if (retval != 0) break; continue; } retval = sbuf_printf(sb, "<size>%ju</size>\n", (lun->be_lun->maxlba > 0) ? lun->be_lun->maxlba + 1 : 0); if (retval != 0) break; retval = sbuf_printf(sb, "<blocksize>%u</blocksize>\n", lun->be_lun->blocksize); if (retval != 0) break; retval = sbuf_printf(sb, "<serial_number>"); if (retval != 0) break; retval = ctl_sbuf_printf_esc(sb, lun->be_lun->serial_num); if (retval != 0) break; retval = sbuf_printf(sb, "</serial_number>\n"); if (retval != 0) break; retval = sbuf_printf(sb, "<device_id>"); if (retval != 0) break; retval = ctl_sbuf_printf_esc(sb,lun->be_lun->device_id); if (retval != 0) break; retval = sbuf_printf(sb, "</device_id>\n"); if (retval != 0) break; if (lun->backend->lun_info == NULL) { retval = sbuf_printf(sb, "</lun>\n"); if (retval != 0) break; continue; } retval =lun->backend->lun_info(lun->be_lun->be_lun, sb); if (retval != 0) break; retval = sbuf_printf(sb, "</lun>\n"); if (retval != 0) break; } mtx_unlock(&softc->ctl_lock); if ((retval != 0) || ((retval = sbuf_printf(sb, "</ctllunlist>\n")) != 0)) { retval = 0; sbuf_delete(sb); list->status = CTL_LUN_LIST_NEED_MORE_SPACE; snprintf(list->error_str, sizeof(list->error_str), "Out of space, %d bytes is too small", list->alloc_len); break; } sbuf_finish(sb); retval = copyout(sbuf_data(sb), list->lun_xml, sbuf_len(sb) + 1); list->fill_len = sbuf_len(sb) + 1; list->status = CTL_LUN_LIST_OK; sbuf_delete(sb); break; } default: { /* XXX KDM should we fix this? */ #if 0 struct ctl_backend_driver *backend; unsigned int type; int found; found = 0; /* * We encode the backend type as the ioctl type for backend * ioctls. So parse it out here, and then search for a * backend of this type. */ type = _IOC_TYPE(cmd); STAILQ_FOREACH(backend, &softc->be_list, links) { if (backend->type == type) { found = 1; break; } } if (found == 0) { printf("ctl: unknown ioctl command %#lx or backend " "%d\n", cmd, type); retval = -EINVAL; break; } retval = backend->ioctl(dev, cmd, addr, flag, td); #endif retval = ENOTTY; break; } } return (retval); } uint32_t ctl_get_initindex(struct ctl_nexus *nexus) { if (nexus->targ_port < CTL_MAX_PORTS) return (nexus->initid.id + (nexus->targ_port * CTL_MAX_INIT_PER_PORT)); else return (nexus->initid.id + ((nexus->targ_port - CTL_MAX_PORTS) * CTL_MAX_INIT_PER_PORT)); } uint32_t ctl_get_resindex(struct ctl_nexus *nexus) { return (nexus->initid.id + (nexus->targ_port * CTL_MAX_INIT_PER_PORT)); } uint32_t ctl_port_idx(int port_num) { if (port_num < CTL_MAX_PORTS) return(port_num); else return(port_num - CTL_MAX_PORTS); } /* * Note: This only works for bitmask sizes that are at least 32 bits, and * that are a power of 2. */ int ctl_ffz(uint32_t *mask, uint32_t size) { uint32_t num_chunks, num_pieces; int i, j; num_chunks = (size >> 5); if (num_chunks == 0) num_chunks++; num_pieces = ctl_min((sizeof(uint32_t) * 8), size); for (i = 0; i < num_chunks; i++) { for (j = 0; j < num_pieces; j++) { if ((mask[i] & (1 << j)) == 0) return ((i << 5) + j); } } return (-1); } int ctl_set_mask(uint32_t *mask, uint32_t bit) { uint32_t chunk, piece; chunk = bit >> 5; piece = bit % (sizeof(uint32_t) * 8); if ((mask[chunk] & (1 << piece)) != 0) return (-1); else mask[chunk] |= (1 << piece); return (0); } int ctl_clear_mask(uint32_t *mask, uint32_t bit) { uint32_t chunk, piece; chunk = bit >> 5; piece = bit % (sizeof(uint32_t) * 8); if ((mask[chunk] & (1 << piece)) == 0) return (-1); else mask[chunk] &= ~(1 << piece); return (0); } int ctl_is_set(uint32_t *mask, uint32_t bit) { uint32_t chunk, piece; chunk = bit >> 5; piece = bit % (sizeof(uint32_t) * 8); if ((mask[chunk] & (1 << piece)) == 0) return (0); else return (1); } #ifdef unused /* * The bus, target and lun are optional, they can be filled in later. * can_wait is used to determine whether we can wait on the malloc or not. */ union ctl_io* ctl_malloc_io(ctl_io_type io_type, uint32_t targ_port, uint32_t targ_target, uint32_t targ_lun, int can_wait) { union ctl_io *io; if (can_wait) io = (union ctl_io *)malloc(sizeof(*io), M_CTL, M_WAITOK); else io = (union ctl_io *)malloc(sizeof(*io), M_CTL, M_NOWAIT); if (io != NULL) { io->io_hdr.io_type = io_type; io->io_hdr.targ_port = targ_port; /* * XXX KDM this needs to change/go away. We need to move * to a preallocated pool of ctl_scsiio structures. */ io->io_hdr.nexus.targ_target.id = targ_target; io->io_hdr.nexus.targ_lun = targ_lun; } return (io); } void ctl_kfree_io(union ctl_io *io) { free(io, M_CTL); } #endif /* unused */ /* * ctl_softc, pool_type, total_ctl_io are passed in. * npool is passed out. */ int ctl_pool_create(struct ctl_softc *ctl_softc, ctl_pool_type pool_type, uint32_t total_ctl_io, struct ctl_io_pool **npool) { uint32_t i; union ctl_io *cur_io, *next_io; struct ctl_io_pool *pool; int retval; retval = 0; pool = (struct ctl_io_pool *)malloc(sizeof(*pool), M_CTL, M_NOWAIT); if (pool == NULL) { retval = -ENOMEM; goto bailout; } memset(pool, 0, sizeof(*pool)); pool->type = pool_type; pool->ctl_softc = ctl_softc; mtx_lock(&ctl_softc->ctl_lock); pool->id = ctl_softc->cur_pool_id++; mtx_unlock(&ctl_softc->ctl_lock); pool->flags = CTL_POOL_FLAG_NONE; STAILQ_INIT(&pool->free_queue); /* * XXX KDM other options here: * - allocate a page at a time * - allocate one big chunk of memory. * Page allocation might work well, but would take a little more * tracking. */ for (i = 0; i < total_ctl_io; i++) { cur_io = (union ctl_io *)malloc(sizeof(*cur_io), M_CTL, M_NOWAIT); if (cur_io == NULL) { retval = ENOMEM; break; } cur_io->io_hdr.pool = pool; STAILQ_INSERT_TAIL(&pool->free_queue, &cur_io->io_hdr, links); pool->total_ctl_io++; pool->free_ctl_io++; } if (retval != 0) { for (cur_io = (union ctl_io *)STAILQ_FIRST(&pool->free_queue); cur_io != NULL; cur_io = next_io) { next_io = (union ctl_io *)STAILQ_NEXT(&cur_io->io_hdr, links); STAILQ_REMOVE(&pool->free_queue, &cur_io->io_hdr, ctl_io_hdr, links); free(cur_io, M_CTL); } free(pool, M_CTL); goto bailout; } mtx_lock(&ctl_softc->ctl_lock); ctl_softc->num_pools++; STAILQ_INSERT_TAIL(&ctl_softc->io_pools, pool, links); /* * Increment our usage count if this is an external consumer, so we * can't get unloaded until the external consumer (most likely a * FETD) unloads and frees his pool. * * XXX KDM will this increment the caller's module use count, or * mine? */ #if 0 if ((pool_type != CTL_POOL_EMERGENCY) && (pool_type != CTL_POOL_INTERNAL) && (pool_type != CTL_POOL_IOCTL) && (pool_type != CTL_POOL_4OTHERSC)) MOD_INC_USE_COUNT; #endif mtx_unlock(&ctl_softc->ctl_lock); *npool = pool; bailout: return (retval); } /* * Caller must hold ctl_softc->ctl_lock. */ int ctl_pool_acquire(struct ctl_io_pool *pool) { if (pool == NULL) return (-EINVAL); if (pool->flags & CTL_POOL_FLAG_INVALID) return (-EINVAL); pool->refcount++; return (0); } /* * Caller must hold ctl_softc->ctl_lock. */ int ctl_pool_invalidate(struct ctl_io_pool *pool) { if (pool == NULL) return (-EINVAL); pool->flags |= CTL_POOL_FLAG_INVALID; return (0); } /* * Caller must hold ctl_softc->ctl_lock. */ int ctl_pool_release(struct ctl_io_pool *pool) { if (pool == NULL) return (-EINVAL); if ((--pool->refcount == 0) && (pool->flags & CTL_POOL_FLAG_INVALID)) { ctl_pool_free(pool->ctl_softc, pool); } return (0); } /* * Must be called with ctl_softc->ctl_lock held. */ void ctl_pool_free(struct ctl_softc *ctl_softc, struct ctl_io_pool *pool) { union ctl_io *cur_io, *next_io; for (cur_io = (union ctl_io *)STAILQ_FIRST(&pool->free_queue); cur_io != NULL; cur_io = next_io) { next_io = (union ctl_io *)STAILQ_NEXT(&cur_io->io_hdr, links); STAILQ_REMOVE(&pool->free_queue, &cur_io->io_hdr, ctl_io_hdr, links); free(cur_io, M_CTL); } STAILQ_REMOVE(&ctl_softc->io_pools, pool, ctl_io_pool, links); ctl_softc->num_pools--; /* * XXX KDM will this decrement the caller's usage count or mine? */ #if 0 if ((pool->type != CTL_POOL_EMERGENCY) && (pool->type != CTL_POOL_INTERNAL) && (pool->type != CTL_POOL_IOCTL)) MOD_DEC_USE_COUNT; #endif free(pool, M_CTL); } /* * This routine does not block (except for spinlocks of course). * It tries to allocate a ctl_io union from the caller's pool as quickly as * possible. */ union ctl_io * ctl_alloc_io(void *pool_ref) { union ctl_io *io; struct ctl_softc *ctl_softc; struct ctl_io_pool *pool, *npool; struct ctl_io_pool *emergency_pool; pool = (struct ctl_io_pool *)pool_ref; if (pool == NULL) { printf("%s: pool is NULL\n", __func__); return (NULL); } emergency_pool = NULL; ctl_softc = pool->ctl_softc; mtx_lock(&ctl_softc->ctl_lock); /* * First, try to get the io structure from the user's pool. */ if (ctl_pool_acquire(pool) == 0) { io = (union ctl_io *)STAILQ_FIRST(&pool->free_queue); if (io != NULL) { STAILQ_REMOVE_HEAD(&pool->free_queue, links); pool->total_allocated++; pool->free_ctl_io--; mtx_unlock(&ctl_softc->ctl_lock); return (io); } else ctl_pool_release(pool); } /* * If he doesn't have any io structures left, search for an * emergency pool and grab one from there. */ STAILQ_FOREACH(npool, &ctl_softc->io_pools, links) { if (npool->type != CTL_POOL_EMERGENCY) continue; if (ctl_pool_acquire(npool) != 0) continue; emergency_pool = npool; io = (union ctl_io *)STAILQ_FIRST(&npool->free_queue); if (io != NULL) { STAILQ_REMOVE_HEAD(&npool->free_queue, links); npool->total_allocated++; npool->free_ctl_io--; mtx_unlock(&ctl_softc->ctl_lock); return (io); } else ctl_pool_release(npool); } /* Drop the spinlock before we malloc */ mtx_unlock(&ctl_softc->ctl_lock); /* * The emergency pool (if it exists) didn't have one, so try an * atomic (i.e. nonblocking) malloc and see if we get lucky. */ io = (union ctl_io *)malloc(sizeof(*io), M_CTL, M_NOWAIT); if (io != NULL) { /* * If the emergency pool exists but is empty, add this * ctl_io to its list when it gets freed. */ if (emergency_pool != NULL) { mtx_lock(&ctl_softc->ctl_lock); if (ctl_pool_acquire(emergency_pool) == 0) { io->io_hdr.pool = emergency_pool; emergency_pool->total_ctl_io++; /* * Need to bump this, otherwise * total_allocated and total_freed won't * match when we no longer have anything * outstanding. */ emergency_pool->total_allocated++; } mtx_unlock(&ctl_softc->ctl_lock); } else io->io_hdr.pool = NULL; } return (io); } static void ctl_free_io_internal(union ctl_io *io, int have_lock) { if (io == NULL) return; /* * If this ctl_io has a pool, return it to that pool. */ if (io->io_hdr.pool != NULL) { struct ctl_io_pool *pool; #if 0 struct ctl_softc *ctl_softc; union ctl_io *tmp_io; unsigned long xflags; int i; ctl_softc = control_softc; #endif pool = (struct ctl_io_pool *)io->io_hdr.pool; if (have_lock == 0) mtx_lock(&pool->ctl_softc->ctl_lock); #if 0 save_flags(xflags); for (i = 0, tmp_io = (union ctl_io *)STAILQ_FIRST( &ctl_softc->task_queue); tmp_io != NULL; i++, tmp_io = (union ctl_io *)STAILQ_NEXT(&tmp_io->io_hdr, links)) { if (tmp_io == io) { printf("%s: %p is still on the task queue!\n", __func__, tmp_io); printf("%s: (%d): type %d " "msg %d cdb %x iptl: " "%d:%d:%d:%d tag 0x%04x " "flg %#lx\n", __func__, i, tmp_io->io_hdr.io_type, tmp_io->io_hdr.msg_type, tmp_io->scsiio.cdb[0], tmp_io->io_hdr.nexus.initid.id, tmp_io->io_hdr.nexus.targ_port, tmp_io->io_hdr.nexus.targ_target.id, tmp_io->io_hdr.nexus.targ_lun, (tmp_io->io_hdr.io_type == CTL_IO_TASK) ? tmp_io->taskio.tag_num : tmp_io->scsiio.tag_num, xflags); panic("I/O still on the task queue!"); } } #endif io->io_hdr.io_type = 0xff; STAILQ_INSERT_TAIL(&pool->free_queue, &io->io_hdr, links); pool->total_freed++; pool->free_ctl_io++; ctl_pool_release(pool); if (have_lock == 0) mtx_unlock(&pool->ctl_softc->ctl_lock); } else { /* * Otherwise, just free it. We probably malloced it and * the emergency pool wasn't available. */ free(io, M_CTL); } } void ctl_free_io(union ctl_io *io) { ctl_free_io_internal(io, /*have_lock*/ 0); } void ctl_zero_io(union ctl_io *io) { void *pool_ref; if (io == NULL) return; /* * May need to preserve linked list pointers at some point too. */ pool_ref = io->io_hdr.pool; memset(io, 0, sizeof(*io)); io->io_hdr.pool = pool_ref; } /* * This routine is currently used for internal copies of ctl_ios that need * to persist for some reason after we've already returned status to the * FETD. (Thus the flag set.) * * XXX XXX * Note that this makes a blind copy of all fields in the ctl_io, except * for the pool reference. This includes any memory that has been * allocated! That memory will no longer be valid after done has been * called, so this would be VERY DANGEROUS for command that actually does * any reads or writes. Right now (11/7/2005), this is only used for immediate * start and stop commands, which don't transfer any data, so this is not a * problem. If it is used for anything else, the caller would also need to * allocate data buffer space and this routine would need to be modified to * copy the data buffer(s) as well. */ void ctl_copy_io(union ctl_io *src, union ctl_io *dest) { void *pool_ref; if ((src == NULL) || (dest == NULL)) return; /* * May need to preserve linked list pointers at some point too. */ pool_ref = dest->io_hdr.pool; memcpy(dest, src, ctl_min(sizeof(*src), sizeof(*dest))); dest->io_hdr.pool = pool_ref; /* * We need to know that this is an internal copy, and doesn't need * to get passed back to the FETD that allocated it. */ dest->io_hdr.flags |= CTL_FLAG_INT_COPY; } #ifdef NEEDTOPORT static void ctl_update_power_subpage(struct copan_power_subpage *page) { int num_luns, num_partitions, config_type; struct ctl_softc *softc; cs_BOOL_t aor_present, shelf_50pct_power; cs_raidset_personality_t rs_type; int max_active_luns; softc = control_softc; /* subtract out the processor LUN */ num_luns = softc->num_luns - 1; /* * Default to 7 LUNs active, which was the only number we allowed * in the past. */ max_active_luns = 7; num_partitions = config_GetRsPartitionInfo(); config_type = config_GetConfigType(); shelf_50pct_power = config_GetShelfPowerMode(); aor_present = config_IsAorRsPresent(); rs_type = ddb_GetRsRaidType(1); if ((rs_type != CS_RAIDSET_PERSONALITY_RAID5) && (rs_type != CS_RAIDSET_PERSONALITY_RAID1)) { EPRINT(0, "Unsupported RS type %d!", rs_type); } page->total_luns = num_luns; switch (config_type) { case 40: /* * In a 40 drive configuration, it doesn't matter what DC * cards we have, whether we have AOR enabled or not, * partitioning or not, or what type of RAIDset we have. * In that scenario, we can power up every LUN we present * to the user. */ max_active_luns = num_luns; break; case 64: if (shelf_50pct_power == CS_FALSE) { /* 25% power */ if (aor_present == CS_TRUE) { if (rs_type == CS_RAIDSET_PERSONALITY_RAID5) { max_active_luns = 7; } else if (rs_type == CS_RAIDSET_PERSONALITY_RAID1){ max_active_luns = 14; } else { /* XXX KDM now what?? */ } } else { if (rs_type == CS_RAIDSET_PERSONALITY_RAID5) { max_active_luns = 8; } else if (rs_type == CS_RAIDSET_PERSONALITY_RAID1){ max_active_luns = 16; } else { /* XXX KDM now what?? */ } } } else { /* 50% power */ /* * With 50% power in a 64 drive configuration, we * can power all LUNs we present. */ max_active_luns = num_luns; } break; case 112: if (shelf_50pct_power == CS_FALSE) { /* 25% power */ if (aor_present == CS_TRUE) { if (rs_type == CS_RAIDSET_PERSONALITY_RAID5) { max_active_luns = 7; } else if (rs_type == CS_RAIDSET_PERSONALITY_RAID1){ max_active_luns = 14; } else { /* XXX KDM now what?? */ } } else { if (rs_type == CS_RAIDSET_PERSONALITY_RAID5) { max_active_luns = 8; } else if (rs_type == CS_RAIDSET_PERSONALITY_RAID1){ max_active_luns = 16; } else { /* XXX KDM now what?? */ } } } else { /* 50% power */ if (aor_present == CS_TRUE) { if (rs_type == CS_RAIDSET_PERSONALITY_RAID5) { max_active_luns = 14; } else if (rs_type == CS_RAIDSET_PERSONALITY_RAID1){ /* * We're assuming here that disk * caching is enabled, and so we're * able to power up half of each * LUN, and cache all writes. */ max_active_luns = num_luns; } else { /* XXX KDM now what?? */ } } else { if (rs_type == CS_RAIDSET_PERSONALITY_RAID5) { max_active_luns = 15; } else if (rs_type == CS_RAIDSET_PERSONALITY_RAID1){ max_active_luns = 30; } else { /* XXX KDM now what?? */ } } } break; default: /* * In this case, we have an unknown configuration, so we * just use the default from above. */ break; } page->max_active_luns = max_active_luns; #if 0 printk("%s: total_luns = %d, max_active_luns = %d\n", __func__, page->total_luns, page->max_active_luns); #endif } #endif /* NEEDTOPORT */ /* * This routine could be used in the future to load default and/or saved * mode page parameters for a particuar lun. */ static int ctl_init_page_index(struct ctl_lun *lun) { int i; struct ctl_page_index *page_index; struct ctl_softc *softc; memcpy(&lun->mode_pages.index, page_index_template, sizeof(page_index_template)); softc = lun->ctl_softc; for (i = 0; i < CTL_NUM_MODE_PAGES; i++) { page_index = &lun->mode_pages.index[i]; /* * If this is a disk-only mode page, there's no point in * setting it up. For some pages, we have to have some * basic information about the disk in order to calculate the * mode page data. */ if ((lun->be_lun->lun_type != T_DIRECT) && (page_index->page_flags & CTL_PAGE_FLAG_DISK_ONLY)) continue; switch (page_index->page_code & SMPH_PC_MASK) { case SMS_FORMAT_DEVICE_PAGE: { struct scsi_format_page *format_page; if (page_index->subpage != SMS_SUBPAGE_PAGE_0) panic("subpage is incorrect!"); /* * Sectors per track are set above. Bytes per * sector need to be set here on a per-LUN basis. */ memcpy(&lun->mode_pages.format_page[CTL_PAGE_CURRENT], &format_page_default, sizeof(format_page_default)); memcpy(&lun->mode_pages.format_page[ CTL_PAGE_CHANGEABLE], &format_page_changeable, sizeof(format_page_changeable)); memcpy(&lun->mode_pages.format_page[CTL_PAGE_DEFAULT], &format_page_default, sizeof(format_page_default)); memcpy(&lun->mode_pages.format_page[CTL_PAGE_SAVED], &format_page_default, sizeof(format_page_default)); format_page = &lun->mode_pages.format_page[ CTL_PAGE_CURRENT]; scsi_ulto2b(lun->be_lun->blocksize, format_page->bytes_per_sector); format_page = &lun->mode_pages.format_page[ CTL_PAGE_DEFAULT]; scsi_ulto2b(lun->be_lun->blocksize, format_page->bytes_per_sector); format_page = &lun->mode_pages.format_page[ CTL_PAGE_SAVED]; scsi_ulto2b(lun->be_lun->blocksize, format_page->bytes_per_sector); page_index->page_data = (uint8_t *)lun->mode_pages.format_page; break; } case SMS_RIGID_DISK_PAGE: { struct scsi_rigid_disk_page *rigid_disk_page; uint32_t sectors_per_cylinder; uint64_t cylinders; #ifndef __XSCALE__ int shift; #endif /* !__XSCALE__ */ if (page_index->subpage != SMS_SUBPAGE_PAGE_0) panic("invalid subpage value %d", page_index->subpage); /* * Rotation rate and sectors per track are set * above. We calculate the cylinders here based on * capacity. Due to the number of heads and * sectors per track we're using, smaller arrays * may turn out to have 0 cylinders. Linux and * FreeBSD don't pay attention to these mode pages * to figure out capacity, but Solaris does. It * seems to deal with 0 cylinders just fine, and * works out a fake geometry based on the capacity. */ memcpy(&lun->mode_pages.rigid_disk_page[ CTL_PAGE_CURRENT], &rigid_disk_page_default, sizeof(rigid_disk_page_default)); memcpy(&lun->mode_pages.rigid_disk_page[ CTL_PAGE_CHANGEABLE],&rigid_disk_page_changeable, sizeof(rigid_disk_page_changeable)); memcpy(&lun->mode_pages.rigid_disk_page[ CTL_PAGE_DEFAULT], &rigid_disk_page_default, sizeof(rigid_disk_page_default)); memcpy(&lun->mode_pages.rigid_disk_page[ CTL_PAGE_SAVED], &rigid_disk_page_default, sizeof(rigid_disk_page_default)); sectors_per_cylinder = CTL_DEFAULT_SECTORS_PER_TRACK * CTL_DEFAULT_HEADS; /* * The divide method here will be more accurate, * probably, but results in floating point being * used in the kernel on i386 (__udivdi3()). On the * XScale, though, __udivdi3() is implemented in * software. * * The shift method for cylinder calculation is * accurate if sectors_per_cylinder is a power of * 2. Otherwise it might be slightly off -- you * might have a bit of a truncation problem. */ #ifdef __XSCALE__ cylinders = (lun->be_lun->maxlba + 1) / sectors_per_cylinder; #else for (shift = 31; shift > 0; shift--) { if (sectors_per_cylinder & (1 << shift)) break; } cylinders = (lun->be_lun->maxlba + 1) >> shift; #endif /* * We've basically got 3 bytes, or 24 bits for the * cylinder size in the mode page. If we're over, * just round down to 2^24. */ if (cylinders > 0xffffff) cylinders = 0xffffff; rigid_disk_page = &lun->mode_pages.rigid_disk_page[ CTL_PAGE_CURRENT]; scsi_ulto3b(cylinders, rigid_disk_page->cylinders); rigid_disk_page = &lun->mode_pages.rigid_disk_page[ CTL_PAGE_DEFAULT]; scsi_ulto3b(cylinders, rigid_disk_page->cylinders); rigid_disk_page = &lun->mode_pages.rigid_disk_page[ CTL_PAGE_SAVED]; scsi_ulto3b(cylinders, rigid_disk_page->cylinders); page_index->page_data = (uint8_t *)lun->mode_pages.rigid_disk_page; break; } case SMS_CACHING_PAGE: { if (page_index->subpage != SMS_SUBPAGE_PAGE_0) panic("invalid subpage value %d", page_index->subpage); /* * Defaults should be okay here, no calculations * needed. */ memcpy(&lun->mode_pages.caching_page[CTL_PAGE_CURRENT], &caching_page_default, sizeof(caching_page_default)); memcpy(&lun->mode_pages.caching_page[ CTL_PAGE_CHANGEABLE], &caching_page_changeable, sizeof(caching_page_changeable)); memcpy(&lun->mode_pages.caching_page[CTL_PAGE_DEFAULT], &caching_page_default, sizeof(caching_page_default)); memcpy(&lun->mode_pages.caching_page[CTL_PAGE_SAVED], &caching_page_default, sizeof(caching_page_default)); page_index->page_data = (uint8_t *)lun->mode_pages.caching_page; break; } case SMS_CONTROL_MODE_PAGE: { if (page_index->subpage != SMS_SUBPAGE_PAGE_0) panic("invalid subpage value %d", page_index->subpage); /* * Defaults should be okay here, no calculations * needed. */ memcpy(&lun->mode_pages.control_page[CTL_PAGE_CURRENT], &control_page_default, sizeof(control_page_default)); memcpy(&lun->mode_pages.control_page[ CTL_PAGE_CHANGEABLE], &control_page_changeable, sizeof(control_page_changeable)); memcpy(&lun->mode_pages.control_page[CTL_PAGE_DEFAULT], &control_page_default, sizeof(control_page_default)); memcpy(&lun->mode_pages.control_page[CTL_PAGE_SAVED], &control_page_default, sizeof(control_page_default)); page_index->page_data = (uint8_t *)lun->mode_pages.control_page; break; } case SMS_VENDOR_SPECIFIC_PAGE:{ switch (page_index->subpage) { case PWR_SUBPAGE_CODE: { struct copan_power_subpage *current_page, *saved_page; memcpy(&lun->mode_pages.power_subpage[ CTL_PAGE_CURRENT], &power_page_default, sizeof(power_page_default)); memcpy(&lun->mode_pages.power_subpage[ CTL_PAGE_CHANGEABLE], &power_page_changeable, sizeof(power_page_changeable)); memcpy(&lun->mode_pages.power_subpage[ CTL_PAGE_DEFAULT], &power_page_default, sizeof(power_page_default)); memcpy(&lun->mode_pages.power_subpage[ CTL_PAGE_SAVED], &power_page_default, sizeof(power_page_default)); page_index->page_data = (uint8_t *)lun->mode_pages.power_subpage; current_page = (struct copan_power_subpage *) (page_index->page_data + (page_index->page_len * CTL_PAGE_CURRENT)); saved_page = (struct copan_power_subpage *) (page_index->page_data + (page_index->page_len * CTL_PAGE_SAVED)); break; } case APS_SUBPAGE_CODE: { struct copan_aps_subpage *current_page, *saved_page; // This gets set multiple times but // it should always be the same. It's // only done during init so who cares. index_to_aps_page = i; memcpy(&lun->mode_pages.aps_subpage[ CTL_PAGE_CURRENT], &aps_page_default, sizeof(aps_page_default)); memcpy(&lun->mode_pages.aps_subpage[ CTL_PAGE_CHANGEABLE], &aps_page_changeable, sizeof(aps_page_changeable)); memcpy(&lun->mode_pages.aps_subpage[ CTL_PAGE_DEFAULT], &aps_page_default, sizeof(aps_page_default)); memcpy(&lun->mode_pages.aps_subpage[ CTL_PAGE_SAVED], &aps_page_default, sizeof(aps_page_default)); page_index->page_data = (uint8_t *)lun->mode_pages.aps_subpage; current_page = (struct copan_aps_subpage *) (page_index->page_data + (page_index->page_len * CTL_PAGE_CURRENT)); saved_page = (struct copan_aps_subpage *) (page_index->page_data + (page_index->page_len * CTL_PAGE_SAVED)); break; } case DBGCNF_SUBPAGE_CODE: { struct copan_debugconf_subpage *current_page, *saved_page; memcpy(&lun->mode_pages.debugconf_subpage[ CTL_PAGE_CURRENT], &debugconf_page_default, sizeof(debugconf_page_default)); memcpy(&lun->mode_pages.debugconf_subpage[ CTL_PAGE_CHANGEABLE], &debugconf_page_changeable, sizeof(debugconf_page_changeable)); memcpy(&lun->mode_pages.debugconf_subpage[ CTL_PAGE_DEFAULT], &debugconf_page_default, sizeof(debugconf_page_default)); memcpy(&lun->mode_pages.debugconf_subpage[ CTL_PAGE_SAVED], &debugconf_page_default, sizeof(debugconf_page_default)); page_index->page_data = (uint8_t *)lun->mode_pages.debugconf_subpage; current_page = (struct copan_debugconf_subpage *) (page_index->page_data + (page_index->page_len * CTL_PAGE_CURRENT)); saved_page = (struct copan_debugconf_subpage *) (page_index->page_data + (page_index->page_len * CTL_PAGE_SAVED)); break; } default: panic("invalid subpage value %d", page_index->subpage); break; } break; } default: panic("invalid page value %d", page_index->page_code & SMPH_PC_MASK); break; } } return (CTL_RETVAL_COMPLETE); } /* * LUN allocation. * * Requirements: * - caller allocates and zeros LUN storage, or passes in a NULL LUN if he * wants us to allocate the LUN and he can block. * - ctl_softc is always set * - be_lun is set if the LUN has a backend (needed for disk LUNs) * * Returns 0 for success, non-zero (errno) for failure. */ static int ctl_alloc_lun(struct ctl_softc *ctl_softc, struct ctl_lun *ctl_lun, struct ctl_be_lun *const be_lun, struct ctl_id target_id) { struct ctl_lun *nlun, *lun; struct ctl_frontend *fe; int lun_number, i; if (be_lun == NULL) return (EINVAL); /* * We currently only support Direct Access or Processor LUN types. */ switch (be_lun->lun_type) { case T_DIRECT: break; case T_PROCESSOR: break; case T_SEQUENTIAL: case T_CHANGER: default: be_lun->lun_config_status(be_lun->be_lun, CTL_LUN_CONFIG_FAILURE); break; } if (ctl_lun == NULL) { lun = malloc(sizeof(*lun), M_CTL, M_WAITOK); if (lun == NULL) { be_lun->lun_config_status(lun->be_lun->be_lun, CTL_LUN_CONFIG_FAILURE); return (-ENOMEM); } lun->flags = CTL_LUN_MALLOCED; } else lun = ctl_lun; memset(lun, 0, sizeof(*lun)); mtx_lock(&ctl_softc->ctl_lock); /* * See if the caller requested a particular LUN number. If so, see * if it is available. Otherwise, allocate the first available LUN. */ if (be_lun->flags & CTL_LUN_FLAG_ID_REQ) { if ((be_lun->req_lun_id > (CTL_MAX_LUNS - 1)) || (ctl_is_set(ctl_softc->ctl_lun_mask, be_lun->req_lun_id))) { mtx_unlock(&ctl_softc->ctl_lock); if (be_lun->req_lun_id > (CTL_MAX_LUNS - 1)) { printf("ctl: requested LUN ID %d is higher " "than CTL_MAX_LUNS - 1 (%d)\n", be_lun->req_lun_id, CTL_MAX_LUNS - 1); } else { /* * XXX KDM return an error, or just assign * another LUN ID in this case?? */ printf("ctl: requested LUN ID %d is already " "in use\n", be_lun->req_lun_id); } if (lun->flags & CTL_LUN_MALLOCED) free(lun, M_CTL); be_lun->lun_config_status(be_lun->be_lun, CTL_LUN_CONFIG_FAILURE); return (ENOSPC); } lun_number = be_lun->req_lun_id; } else { lun_number = ctl_ffz(ctl_softc->ctl_lun_mask, CTL_MAX_LUNS); if (lun_number == -1) { mtx_unlock(&ctl_softc->ctl_lock); printf("ctl: can't allocate LUN on target %ju, out of " "LUNs\n", (uintmax_t)target_id.id); if (lun->flags & CTL_LUN_MALLOCED) free(lun, M_CTL); be_lun->lun_config_status(be_lun->be_lun, CTL_LUN_CONFIG_FAILURE); return (ENOSPC); } } ctl_set_mask(ctl_softc->ctl_lun_mask, lun_number); lun->target = target_id; lun->lun = lun_number; lun->be_lun = be_lun; /* * The processor LUN is always enabled. Disk LUNs come on line * disabled, and must be enabled by the backend. */ lun->flags = CTL_LUN_DISABLED; lun->backend = be_lun->be; be_lun->ctl_lun = lun; be_lun->lun_id = lun_number; atomic_add_int(&be_lun->be->num_luns, 1); if (be_lun->flags & CTL_LUN_FLAG_POWERED_OFF) lun->flags |= CTL_LUN_STOPPED; if (be_lun->flags & CTL_LUN_FLAG_INOPERABLE) lun->flags |= CTL_LUN_INOPERABLE; if (be_lun->flags & CTL_LUN_FLAG_PRIMARY) lun->flags |= CTL_LUN_PRIMARY_SC; lun->ctl_softc = ctl_softc; TAILQ_INIT(&lun->ooa_queue); TAILQ_INIT(&lun->blocked_queue); STAILQ_INIT(&lun->error_list); /* * Initialize the mode page index. */ ctl_init_page_index(lun); /* * Set the poweron UA for all initiators on this LUN only. */ for (i = 0; i < CTL_MAX_INITIATORS; i++) lun->pending_sense[i].ua_pending = CTL_UA_POWERON; /* * Now, before we insert this lun on the lun list, set the lun * inventory changed UA for all other luns. */ STAILQ_FOREACH(nlun, &ctl_softc->lun_list, links) { for (i = 0; i < CTL_MAX_INITIATORS; i++) { nlun->pending_sense[i].ua_pending |= CTL_UA_LUN_CHANGE; } } STAILQ_INSERT_TAIL(&ctl_softc->lun_list, lun, links); ctl_softc->ctl_luns[lun_number] = lun; ctl_softc->num_luns++; /* Setup statistics gathering */ lun->stats.device_type = be_lun->lun_type; lun->stats.lun_number = lun_number; if (lun->stats.device_type == T_DIRECT) lun->stats.blocksize = be_lun->blocksize; else lun->stats.flags = CTL_LUN_STATS_NO_BLOCKSIZE; for (i = 0;i < CTL_MAX_PORTS;i++) lun->stats.ports[i].targ_port = i; mtx_unlock(&ctl_softc->ctl_lock); lun->be_lun->lun_config_status(lun->be_lun->be_lun, CTL_LUN_CONFIG_OK); /* * Run through each registered FETD and bring it online if it isn't * already. Enable the target ID if it hasn't been enabled, and * enable this particular LUN. */ STAILQ_FOREACH(fe, &ctl_softc->fe_list, links) { int retval; /* * XXX KDM this only works for ONE TARGET ID. We'll need * to do things differently if we go to a multiple target * ID scheme. */ if ((fe->status & CTL_PORT_STATUS_TARG_ONLINE) == 0) { retval = fe->targ_enable(fe->targ_lun_arg, target_id); if (retval != 0) { printf("ctl_alloc_lun: FETD %s port %d " "returned error %d for targ_enable on " "target %ju\n", fe->port_name, fe->targ_port, retval, (uintmax_t)target_id.id); } else fe->status |= CTL_PORT_STATUS_TARG_ONLINE; } retval = fe->lun_enable(fe->targ_lun_arg, target_id,lun_number); if (retval != 0) { printf("ctl_alloc_lun: FETD %s port %d returned error " "%d for lun_enable on target %ju lun %d\n", fe->port_name, fe->targ_port, retval, (uintmax_t)target_id.id, lun_number); } else fe->status |= CTL_PORT_STATUS_LUN_ONLINE; } return (0); } /* * Delete a LUN. * Assumptions: * - caller holds ctl_softc->ctl_lock. * - LUN has already been marked invalid and any pending I/O has been taken * care of. */ static int ctl_free_lun(struct ctl_lun *lun) { struct ctl_softc *softc; #if 0 struct ctl_frontend *fe; #endif struct ctl_lun *nlun; union ctl_io *io, *next_io; int i; softc = lun->ctl_softc; STAILQ_REMOVE(&softc->lun_list, lun, ctl_lun, links); ctl_clear_mask(softc->ctl_lun_mask, lun->lun); softc->ctl_luns[lun->lun] = NULL; if (TAILQ_FIRST(&lun->ooa_queue) != NULL) { printf("ctl_free_lun: aieee!! freeing a LUN with " "outstanding I/O!!\n"); } /* * If we have anything pending on the RtR queue, remove it. */ for (io = (union ctl_io *)STAILQ_FIRST(&softc->rtr_queue); io != NULL; io = next_io) { next_io = (union ctl_io *)STAILQ_NEXT(&io->io_hdr, links); if ((io->io_hdr.nexus.targ_target.id == lun->target.id) && (io->io_hdr.nexus.targ_lun == lun->lun)) STAILQ_REMOVE(&softc->rtr_queue, &io->io_hdr, ctl_io_hdr, links); } /* * Then remove everything from the blocked queue. */ for (io = (union ctl_io *)TAILQ_FIRST(&lun->blocked_queue); io != NULL; io = next_io) { next_io = (union ctl_io *)TAILQ_NEXT(&io->io_hdr,blocked_links); TAILQ_REMOVE(&lun->blocked_queue, &io->io_hdr, blocked_links); io->io_hdr.flags &= ~CTL_FLAG_BLOCKED; } /* * Now clear out the OOA queue, and free all the I/O. * XXX KDM should we notify the FETD here? We probably need to * quiesce the LUN before deleting it. */ for (io = (union ctl_io *)TAILQ_FIRST(&lun->ooa_queue); io != NULL; io = next_io) { next_io = (union ctl_io *)TAILQ_NEXT(&io->io_hdr, ooa_links); TAILQ_REMOVE(&lun->ooa_queue, &io->io_hdr, ooa_links); ctl_free_io_internal(io, /*have_lock*/ 1); } softc->num_luns--; /* * XXX KDM this scheme only works for a single target/multiple LUN * setup. It needs to be revamped for a multiple target scheme. * * XXX KDM this results in fe->lun_disable() getting called twice, * once when ctl_disable_lun() is called, and a second time here. * We really need to re-think the LUN disable semantics. There * should probably be several steps/levels to LUN removal: * - disable * - invalidate * - free * * Right now we only have a disable method when communicating to * the front end ports, at least for individual LUNs. */ #if 0 STAILQ_FOREACH(fe, &softc->fe_list, links) { int retval; retval = fe->lun_disable(fe->targ_lun_arg, lun->target, lun->lun); if (retval != 0) { printf("ctl_free_lun: FETD %s port %d returned error " "%d for lun_disable on target %ju lun %jd\n", fe->port_name, fe->targ_port, retval, (uintmax_t)lun->target.id, (intmax_t)lun->lun); } if (STAILQ_FIRST(&softc->lun_list) == NULL) { fe->status &= ~CTL_PORT_STATUS_LUN_ONLINE; retval = fe->targ_disable(fe->targ_lun_arg,lun->target); if (retval != 0) { printf("ctl_free_lun: FETD %s port %d " "returned error %d for targ_disable on " "target %ju\n", fe->port_name, fe->targ_port, retval, (uintmax_t)lun->target.id); } else fe->status &= ~CTL_PORT_STATUS_TARG_ONLINE; if ((fe->status & CTL_PORT_STATUS_TARG_ONLINE) != 0) continue; #if 0 fe->port_offline(fe->onoff_arg); fe->status &= ~CTL_PORT_STATUS_ONLINE; #endif } } #endif /* * Tell the backend to free resources, if this LUN has a backend. */ atomic_subtract_int(&lun->be_lun->be->num_luns, 1); lun->be_lun->lun_shutdown(lun->be_lun->be_lun); if (lun->flags & CTL_LUN_MALLOCED) free(lun, M_CTL); STAILQ_FOREACH(nlun, &softc->lun_list, links) { for (i = 0; i < CTL_MAX_INITIATORS; i++) { nlun->pending_sense[i].ua_pending |= CTL_UA_LUN_CHANGE; } } return (0); } static void ctl_create_lun(struct ctl_be_lun *be_lun) { struct ctl_softc *ctl_softc; ctl_softc = control_softc; /* * ctl_alloc_lun() should handle all potential failure cases. */ ctl_alloc_lun(ctl_softc, NULL, be_lun, ctl_softc->target); } int ctl_add_lun(struct ctl_be_lun *be_lun) { struct ctl_softc *ctl_softc; ctl_softc = control_softc; mtx_lock(&ctl_softc->ctl_lock); STAILQ_INSERT_TAIL(&ctl_softc->pending_lun_queue, be_lun, links); mtx_unlock(&ctl_softc->ctl_lock); ctl_wakeup_thread(); return (0); } int ctl_enable_lun(struct ctl_be_lun *be_lun) { struct ctl_softc *ctl_softc; struct ctl_frontend *fe, *nfe; struct ctl_lun *lun; int retval; ctl_softc = control_softc; lun = (struct ctl_lun *)be_lun->ctl_lun; mtx_lock(&ctl_softc->ctl_lock); if ((lun->flags & CTL_LUN_DISABLED) == 0) { /* * eh? Why did we get called if the LUN is already * enabled? */ mtx_unlock(&ctl_softc->ctl_lock); return (0); } lun->flags &= ~CTL_LUN_DISABLED; for (fe = STAILQ_FIRST(&ctl_softc->fe_list); fe != NULL; fe = nfe) { nfe = STAILQ_NEXT(fe, links); /* * Drop the lock while we call the FETD's enable routine. * This can lead to a callback into CTL (at least in the * case of the internal initiator frontend. */ mtx_unlock(&ctl_softc->ctl_lock); retval = fe->lun_enable(fe->targ_lun_arg, lun->target,lun->lun); mtx_lock(&ctl_softc->ctl_lock); if (retval != 0) { printf("%s: FETD %s port %d returned error " "%d for lun_enable on target %ju lun %jd\n", __func__, fe->port_name, fe->targ_port, retval, (uintmax_t)lun->target.id, (intmax_t)lun->lun); } #if 0 else { /* NOTE: TODO: why does lun enable affect port status? */ fe->status |= CTL_PORT_STATUS_LUN_ONLINE; } #endif } mtx_unlock(&ctl_softc->ctl_lock); return (0); } int ctl_disable_lun(struct ctl_be_lun *be_lun) { struct ctl_softc *ctl_softc; struct ctl_frontend *fe; struct ctl_lun *lun; int retval; ctl_softc = control_softc; lun = (struct ctl_lun *)be_lun->ctl_lun; mtx_lock(&ctl_softc->ctl_lock); if (lun->flags & CTL_LUN_DISABLED) { mtx_unlock(&ctl_softc->ctl_lock); return (0); } lun->flags |= CTL_LUN_DISABLED; STAILQ_FOREACH(fe, &ctl_softc->fe_list, links) { mtx_unlock(&ctl_softc->ctl_lock); /* * Drop the lock before we call the frontend's disable * routine, to avoid lock order reversals. * * XXX KDM what happens if the frontend list changes while * we're traversing it? It's unlikely, but should be handled. */ retval = fe->lun_disable(fe->targ_lun_arg, lun->target, lun->lun); mtx_lock(&ctl_softc->ctl_lock); if (retval != 0) { printf("ctl_alloc_lun: FETD %s port %d returned error " "%d for lun_disable on target %ju lun %jd\n", fe->port_name, fe->targ_port, retval, (uintmax_t)lun->target.id, (intmax_t)lun->lun); } } mtx_unlock(&ctl_softc->ctl_lock); return (0); } int ctl_start_lun(struct ctl_be_lun *be_lun) { struct ctl_softc *ctl_softc; struct ctl_lun *lun; ctl_softc = control_softc; lun = (struct ctl_lun *)be_lun->ctl_lun; mtx_lock(&ctl_softc->ctl_lock); lun->flags &= ~CTL_LUN_STOPPED; mtx_unlock(&ctl_softc->ctl_lock); return (0); } int ctl_stop_lun(struct ctl_be_lun *be_lun) { struct ctl_softc *ctl_softc; struct ctl_lun *lun; ctl_softc = control_softc; lun = (struct ctl_lun *)be_lun->ctl_lun; mtx_lock(&ctl_softc->ctl_lock); lun->flags |= CTL_LUN_STOPPED; mtx_unlock(&ctl_softc->ctl_lock); return (0); } int ctl_lun_offline(struct ctl_be_lun *be_lun) { struct ctl_softc *ctl_softc; struct ctl_lun *lun; ctl_softc = control_softc; lun = (struct ctl_lun *)be_lun->ctl_lun; mtx_lock(&ctl_softc->ctl_lock); lun->flags |= CTL_LUN_OFFLINE; mtx_unlock(&ctl_softc->ctl_lock); return (0); } int ctl_lun_online(struct ctl_be_lun *be_lun) { struct ctl_softc *ctl_softc; struct ctl_lun *lun; ctl_softc = control_softc; lun = (struct ctl_lun *)be_lun->ctl_lun; mtx_lock(&ctl_softc->ctl_lock); lun->flags &= ~CTL_LUN_OFFLINE; mtx_unlock(&ctl_softc->ctl_lock); return (0); } int ctl_invalidate_lun(struct ctl_be_lun *be_lun) { struct ctl_softc *ctl_softc; struct ctl_lun *lun; ctl_softc = control_softc; lun = (struct ctl_lun *)be_lun->ctl_lun; mtx_lock(&ctl_softc->ctl_lock); /* * The LUN needs to be disabled before it can be marked invalid. */ if ((lun->flags & CTL_LUN_DISABLED) == 0) { mtx_unlock(&ctl_softc->ctl_lock); return (-1); } /* * Mark the LUN invalid. */ lun->flags |= CTL_LUN_INVALID; /* * If there is nothing in the OOA queue, go ahead and free the LUN. * If we have something in the OOA queue, we'll free it when the * last I/O completes. */ if (TAILQ_FIRST(&lun->ooa_queue) == NULL) ctl_free_lun(lun); mtx_unlock(&ctl_softc->ctl_lock); return (0); } int ctl_lun_inoperable(struct ctl_be_lun *be_lun) { struct ctl_softc *ctl_softc; struct ctl_lun *lun; ctl_softc = control_softc; lun = (struct ctl_lun *)be_lun->ctl_lun; mtx_lock(&ctl_softc->ctl_lock); lun->flags |= CTL_LUN_INOPERABLE; mtx_unlock(&ctl_softc->ctl_lock); return (0); } int ctl_lun_operable(struct ctl_be_lun *be_lun) { struct ctl_softc *ctl_softc; struct ctl_lun *lun; ctl_softc = control_softc; lun = (struct ctl_lun *)be_lun->ctl_lun; mtx_lock(&ctl_softc->ctl_lock); lun->flags &= ~CTL_LUN_INOPERABLE; mtx_unlock(&ctl_softc->ctl_lock); return (0); } int ctl_lun_power_lock(struct ctl_be_lun *be_lun, struct ctl_nexus *nexus, int lock) { struct ctl_softc *softc; struct ctl_lun *lun; struct copan_aps_subpage *current_sp; struct ctl_page_index *page_index; int i; softc = control_softc; mtx_lock(&softc->ctl_lock); lun = (struct ctl_lun *)be_lun->ctl_lun; page_index = NULL; for (i = 0; i < CTL_NUM_MODE_PAGES; i++) { if ((lun->mode_pages.index[i].page_code & SMPH_PC_MASK) != APS_PAGE_CODE) continue; if (lun->mode_pages.index[i].subpage != APS_SUBPAGE_CODE) continue; page_index = &lun->mode_pages.index[i]; } if (page_index == NULL) { mtx_unlock(&softc->ctl_lock); printf("%s: APS subpage not found for lun %ju!\n", __func__, (uintmax_t)lun->lun); return (1); } #if 0 if ((softc->aps_locked_lun != 0) && (softc->aps_locked_lun != lun->lun)) { printf("%s: attempt to lock LUN %llu when %llu is already " "locked\n"); mtx_unlock(&softc->ctl_lock); return (1); } #endif current_sp = (struct copan_aps_subpage *)(page_index->page_data + (page_index->page_len * CTL_PAGE_CURRENT)); if (lock != 0) { current_sp->lock_active = APS_LOCK_ACTIVE; softc->aps_locked_lun = lun->lun; } else { current_sp->lock_active = 0; softc->aps_locked_lun = 0; } /* * If we're in HA mode, try to send the lock message to the other * side. */ if (ctl_is_single == 0) { int isc_retval; union ctl_ha_msg lock_msg; lock_msg.hdr.nexus = *nexus; lock_msg.hdr.msg_type = CTL_MSG_APS_LOCK; if (lock != 0) lock_msg.aps.lock_flag = 1; else lock_msg.aps.lock_flag = 0; isc_retval = ctl_ha_msg_send(CTL_HA_CHAN_CTL, &lock_msg, sizeof(lock_msg), 0); if (isc_retval > CTL_HA_STATUS_SUCCESS) { printf("%s: APS (lock=%d) error returned from " "ctl_ha_msg_send: %d\n", __func__, lock, isc_retval); mtx_unlock(&softc->ctl_lock); return (1); } } mtx_unlock(&softc->ctl_lock); return (0); } void ctl_lun_capacity_changed(struct ctl_be_lun *be_lun) { struct ctl_lun *lun; struct ctl_softc *softc; int i; softc = control_softc; mtx_lock(&softc->ctl_lock); lun = (struct ctl_lun *)be_lun->ctl_lun; for (i = 0; i < CTL_MAX_INITIATORS; i++) lun->pending_sense[i].ua_pending |= CTL_UA_CAPACITY_CHANGED; mtx_unlock(&softc->ctl_lock); } /* * Backend "memory move is complete" callback for requests that never * make it down to say RAIDCore's configuration code. */ int ctl_config_move_done(union ctl_io *io) { int retval; retval = CTL_RETVAL_COMPLETE; CTL_DEBUG_PRINT(("ctl_config_move_done\n")); /* * XXX KDM this shouldn't happen, but what if it does? */ if (io->io_hdr.io_type != CTL_IO_SCSI) panic("I/O type isn't CTL_IO_SCSI!"); if ((io->io_hdr.port_status == 0) && ((io->io_hdr.flags & CTL_FLAG_ABORT) == 0) && ((io->io_hdr.status & CTL_STATUS_MASK) == CTL_STATUS_NONE)) io->io_hdr.status = CTL_SUCCESS; else if ((io->io_hdr.port_status != 0) && ((io->io_hdr.flags & CTL_FLAG_ABORT) == 0) && ((io->io_hdr.status & CTL_STATUS_MASK) == CTL_STATUS_NONE)){ /* * For hardware error sense keys, the sense key * specific value is defined to be a retry count, * but we use it to pass back an internal FETD * error code. XXX KDM Hopefully the FETD is only * using 16 bits for an error code, since that's * all the space we have in the sks field. */ ctl_set_internal_failure(&io->scsiio, /*sks_valid*/ 1, /*retry_count*/ io->io_hdr.port_status); free(io->scsiio.kern_data_ptr, M_CTL); ctl_done(io); goto bailout; } if (((io->io_hdr.flags & CTL_FLAG_DATA_MASK) == CTL_FLAG_DATA_IN) || ((io->io_hdr.status & CTL_STATUS_MASK) != CTL_SUCCESS) || ((io->io_hdr.flags & CTL_FLAG_ABORT) != 0)) { /* * XXX KDM just assuming a single pointer here, and not a * S/G list. If we start using S/G lists for config data, * we'll need to know how to clean them up here as well. */ free(io->scsiio.kern_data_ptr, M_CTL); /* Hopefully the user has already set the status... */ ctl_done(io); } else { /* * XXX KDM now we need to continue data movement. Some * options: * - call ctl_scsiio() again? We don't do this for data * writes, because for those at least we know ahead of * time where the write will go and how long it is. For * config writes, though, that information is largely * contained within the write itself, thus we need to * parse out the data again. * * - Call some other function once the data is in? */ /* * XXX KDM call ctl_scsiio() again for now, and check flag * bits to see whether we're allocated or not. */ retval = ctl_scsiio(&io->scsiio); } bailout: return (retval); } /* * This gets called by a backend driver when it is done with a * configuration write. */ void ctl_config_write_done(union ctl_io *io) { /* * If the IO_CONT flag is set, we need to call the supplied * function to continue processing the I/O, instead of completing * the I/O just yet. * * If there is an error, though, we don't want to keep processing. * Instead, just send status back to the initiator. */ if ((io->io_hdr.flags & CTL_FLAG_IO_CONT) && (((io->io_hdr.status & CTL_STATUS_MASK) == CTL_STATUS_NONE) || ((io->io_hdr.status & CTL_STATUS_MASK) == CTL_SUCCESS))) { io->scsiio.io_cont(io); return; } /* * Since a configuration write can be done for commands that actually * have data allocated, like write buffer, and commands that have * no data, like start/stop unit, we need to check here. */ if ((io->io_hdr.flags & CTL_FLAG_DATA_MASK) == CTL_FLAG_DATA_OUT) free(io->scsiio.kern_data_ptr, M_CTL); ctl_done(io); } /* * SCSI release command. */ int ctl_scsi_release(struct ctl_scsiio *ctsio) { int length, longid, thirdparty_id, resv_id; struct ctl_softc *ctl_softc; struct ctl_lun *lun; length = 0; resv_id = 0; CTL_DEBUG_PRINT(("ctl_scsi_release\n")); lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; ctl_softc = control_softc; switch (ctsio->cdb[0]) { case RELEASE: { struct scsi_release *cdb; cdb = (struct scsi_release *)ctsio->cdb; if ((cdb->byte2 & 0x1f) != 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 1, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } break; } case RELEASE_10: { struct scsi_release_10 *cdb; cdb = (struct scsi_release_10 *)ctsio->cdb; if ((cdb->byte2 & SR10_EXTENT) != 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 1, /*bit_valid*/ 1, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } if ((cdb->byte2 & SR10_3RDPTY) != 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 1, /*bit_valid*/ 1, /*bit*/ 4); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } if (cdb->byte2 & SR10_LONGID) longid = 1; else thirdparty_id = cdb->thirdparty_id; resv_id = cdb->resv_id; length = scsi_2btoul(cdb->length); break; } } /* * XXX KDM right now, we only support LUN reservation. We don't * support 3rd party reservations, or extent reservations, which * might actually need the parameter list. If we've gotten this * far, we've got a LUN reservation. Anything else got kicked out * above. So, according to SPC, ignore the length. */ length = 0; if (((ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) == 0) && (length > 0)) { ctsio->kern_data_ptr = malloc(length, M_CTL, M_WAITOK); if (ctsio->kern_data_ptr == NULL) { ctsio->io_hdr.status = CTL_SCSI_ERROR; ctsio->io_hdr.status = SCSI_STATUS_BUSY; ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } ctsio->kern_data_len = length; ctsio->kern_total_len = length; ctsio->kern_data_resid = 0; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } if (length > 0) thirdparty_id = scsi_8btou64(ctsio->kern_data_ptr); mtx_lock(&ctl_softc->ctl_lock); /* * According to SPC, it is not an error for an intiator to attempt * to release a reservation on a LUN that isn't reserved, or that * is reserved by another initiator. The reservation can only be * released, though, by the initiator who made it or by one of * several reset type events. */ if (lun->flags & CTL_LUN_RESERVED) { if ((ctsio->io_hdr.nexus.initid.id == lun->rsv_nexus.initid.id) && (ctsio->io_hdr.nexus.targ_port == lun->rsv_nexus.targ_port) && (ctsio->io_hdr.nexus.targ_target.id == lun->rsv_nexus.targ_target.id)) { lun->flags &= ~CTL_LUN_RESERVED; } } ctsio->scsi_status = SCSI_STATUS_OK; ctsio->io_hdr.status = CTL_SUCCESS; if (ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) { free(ctsio->kern_data_ptr, M_CTL); ctsio->io_hdr.flags &= ~CTL_FLAG_ALLOCATED; } mtx_unlock(&ctl_softc->ctl_lock); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_scsi_reserve(struct ctl_scsiio *ctsio) { int extent, thirdparty, longid; int resv_id, length; uint64_t thirdparty_id; struct ctl_softc *ctl_softc; struct ctl_lun *lun; extent = 0; thirdparty = 0; longid = 0; resv_id = 0; length = 0; thirdparty_id = 0; CTL_DEBUG_PRINT(("ctl_reserve\n")); lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; ctl_softc = control_softc; switch (ctsio->cdb[0]) { case RESERVE: { struct scsi_reserve *cdb; cdb = (struct scsi_reserve *)ctsio->cdb; if ((cdb->byte2 & 0x1f) != 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 1, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } resv_id = cdb->resv_id; length = scsi_2btoul(cdb->length); break; } case RESERVE_10: { struct scsi_reserve_10 *cdb; cdb = (struct scsi_reserve_10 *)ctsio->cdb; if ((cdb->byte2 & SR10_EXTENT) != 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 1, /*bit_valid*/ 1, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } if ((cdb->byte2 & SR10_3RDPTY) != 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 1, /*bit_valid*/ 1, /*bit*/ 4); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } if (cdb->byte2 & SR10_LONGID) longid = 1; else thirdparty_id = cdb->thirdparty_id; resv_id = cdb->resv_id; length = scsi_2btoul(cdb->length); break; } } /* * XXX KDM right now, we only support LUN reservation. We don't * support 3rd party reservations, or extent reservations, which * might actually need the parameter list. If we've gotten this * far, we've got a LUN reservation. Anything else got kicked out * above. So, according to SPC, ignore the length. */ length = 0; if (((ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) == 0) && (length > 0)) { ctsio->kern_data_ptr = malloc(length, M_CTL, M_WAITOK); if (ctsio->kern_data_ptr == NULL) { ctsio->io_hdr.status = CTL_SCSI_ERROR; ctsio->io_hdr.status = SCSI_STATUS_BUSY; ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } ctsio->kern_data_len = length; ctsio->kern_total_len = length; ctsio->kern_data_resid = 0; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } if (length > 0) thirdparty_id = scsi_8btou64(ctsio->kern_data_ptr); mtx_lock(&ctl_softc->ctl_lock); if (lun->flags & CTL_LUN_RESERVED) { if ((ctsio->io_hdr.nexus.initid.id != lun->rsv_nexus.initid.id) || (ctsio->io_hdr.nexus.targ_port != lun->rsv_nexus.targ_port) || (ctsio->io_hdr.nexus.targ_target.id != lun->rsv_nexus.targ_target.id)) { ctsio->scsi_status = SCSI_STATUS_RESERV_CONFLICT; ctsio->io_hdr.status = CTL_SCSI_ERROR; goto bailout; } } lun->flags |= CTL_LUN_RESERVED; lun->rsv_nexus = ctsio->io_hdr.nexus; ctsio->scsi_status = SCSI_STATUS_OK; ctsio->io_hdr.status = CTL_SUCCESS; bailout: if (ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) { free(ctsio->kern_data_ptr, M_CTL); ctsio->io_hdr.flags &= ~CTL_FLAG_ALLOCATED; } mtx_unlock(&ctl_softc->ctl_lock); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_start_stop(struct ctl_scsiio *ctsio) { struct scsi_start_stop_unit *cdb; struct ctl_lun *lun; struct ctl_softc *ctl_softc; int retval; CTL_DEBUG_PRINT(("ctl_start_stop\n")); lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; ctl_softc = control_softc; retval = 0; cdb = (struct scsi_start_stop_unit *)ctsio->cdb; /* * XXX KDM * We don't support the immediate bit on a stop unit. In order to * do that, we would need to code up a way to know that a stop is * pending, and hold off any new commands until it completes, one * way or another. Then we could accept or reject those commands * depending on its status. We would almost need to do the reverse * of what we do below for an immediate start -- return the copy of * the ctl_io to the FETD with status to send to the host (and to * free the copy!) and then free the original I/O once the stop * actually completes. That way, the OOA queue mechanism can work * to block commands that shouldn't proceed. Another alternative * would be to put the copy in the queue in place of the original, * and return the original back to the caller. That could be * slightly safer.. */ if ((cdb->byte2 & SSS_IMMED) && ((cdb->how & SSS_START) == 0)) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 1, /*bit_valid*/ 1, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * We don't support the power conditions field. We need to check * this prior to checking the load/eject and start/stop bits. */ if ((cdb->how & SSS_PC_MASK) != SSS_PC_START_VALID) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 4, /*bit_valid*/ 1, /*bit*/ 4); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * Media isn't removable, so we can't load or eject it. */ if ((cdb->how & SSS_LOEJ) != 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 4, /*bit_valid*/ 1, /*bit*/ 1); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } if ((lun->flags & CTL_LUN_PR_RESERVED) && ((cdb->how & SSS_START)==0)) { uint32_t residx; residx = ctl_get_resindex(&ctsio->io_hdr.nexus); if (!lun->per_res[residx].registered || (lun->pr_res_idx!=residx && lun->res_type < 4)) { ctl_set_reservation_conflict(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } } /* * If there is no backend on this device, we can't start or stop * it. In theory we shouldn't get any start/stop commands in the * first place at this level if the LUN doesn't have a backend. * That should get stopped by the command decode code. */ if (lun->backend == NULL) { ctl_set_invalid_opcode(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * XXX KDM Copan-specific offline behavior. * Figure out a reasonable way to port this? */ #ifdef NEEDTOPORT mtx_lock(&ctl_softc->ctl_lock); if (((cdb->byte2 & SSS_ONOFFLINE) == 0) && (lun->flags & CTL_LUN_OFFLINE)) { /* * If the LUN is offline, and the on/offline bit isn't set, * reject the start or stop. Otherwise, let it through. */ mtx_unlock(&ctl_softc->ctl_lock); ctl_set_lun_not_ready(ctsio); ctl_done((union ctl_io *)ctsio); } else { mtx_unlock(&ctl_softc->ctl_lock); #endif /* NEEDTOPORT */ /* * This could be a start or a stop when we're online, * or a stop/offline or start/online. A start or stop when * we're offline is covered in the case above. */ /* * In the non-immediate case, we send the request to * the backend and return status to the user when * it is done. * * In the immediate case, we allocate a new ctl_io * to hold a copy of the request, and send that to * the backend. We then set good status on the * user's request and return it immediately. */ if (cdb->byte2 & SSS_IMMED) { union ctl_io *new_io; new_io = ctl_alloc_io(ctsio->io_hdr.pool); if (new_io == NULL) { ctl_set_busy(ctsio); ctl_done((union ctl_io *)ctsio); } else { ctl_copy_io((union ctl_io *)ctsio, new_io); retval = lun->backend->config_write(new_io); ctl_set_success(ctsio); ctl_done((union ctl_io *)ctsio); } } else { retval = lun->backend->config_write( (union ctl_io *)ctsio); } #ifdef NEEDTOPORT } #endif return (retval); } /* * We support the SYNCHRONIZE CACHE command (10 and 16 byte versions), but * we don't really do anything with the LBA and length fields if the user * passes them in. Instead we'll just flush out the cache for the entire * LUN. */ int ctl_sync_cache(struct ctl_scsiio *ctsio) { struct ctl_lun *lun; struct ctl_softc *ctl_softc; uint64_t starting_lba; uint32_t block_count; int reladr, immed; int retval; CTL_DEBUG_PRINT(("ctl_sync_cache\n")); lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; ctl_softc = control_softc; retval = 0; reladr = 0; immed = 0; switch (ctsio->cdb[0]) { case SYNCHRONIZE_CACHE: { struct scsi_sync_cache *cdb; cdb = (struct scsi_sync_cache *)ctsio->cdb; if (cdb->byte2 & SSC_RELADR) reladr = 1; if (cdb->byte2 & SSC_IMMED) immed = 1; starting_lba = scsi_4btoul(cdb->begin_lba); block_count = scsi_2btoul(cdb->lb_count); break; } case SYNCHRONIZE_CACHE_16: { struct scsi_sync_cache_16 *cdb; cdb = (struct scsi_sync_cache_16 *)ctsio->cdb; if (cdb->byte2 & SSC_RELADR) reladr = 1; if (cdb->byte2 & SSC_IMMED) immed = 1; starting_lba = scsi_8btou64(cdb->begin_lba); block_count = scsi_4btoul(cdb->lb_count); break; } default: ctl_set_invalid_opcode(ctsio); ctl_done((union ctl_io *)ctsio); goto bailout; break; /* NOTREACHED */ } if (immed) { /* * We don't support the immediate bit. Since it's in the * same place for the 10 and 16 byte SYNCHRONIZE CACHE * commands, we can just return the same error in either * case. */ ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 1, /*bit_valid*/ 1, /*bit*/ 1); ctl_done((union ctl_io *)ctsio); goto bailout; } if (reladr) { /* * We don't support the reladr bit either. It can only be * used with linked commands, and we don't support linked * commands. Since the bit is in the same place for the * 10 and 16 byte SYNCHRONIZE CACHE * commands, we can * just return the same error in either case. */ ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 1, /*bit_valid*/ 1, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); goto bailout; } /* * We check the LBA and length, but don't do anything with them. * A SYNCHRONIZE CACHE will cause the entire cache for this lun to * get flushed. This check will just help satisfy anyone who wants * to see an error for an out of range LBA. */ if ((starting_lba + block_count) > (lun->be_lun->maxlba + 1)) { ctl_set_lba_out_of_range(ctsio); ctl_done((union ctl_io *)ctsio); goto bailout; } /* * If this LUN has no backend, we can't flush the cache anyway. */ if (lun->backend == NULL) { ctl_set_invalid_opcode(ctsio); ctl_done((union ctl_io *)ctsio); goto bailout; } /* * Check to see whether we're configured to send the SYNCHRONIZE * CACHE command directly to the back end. */ mtx_lock(&ctl_softc->ctl_lock); if ((ctl_softc->flags & CTL_FLAG_REAL_SYNC) && (++(lun->sync_count) >= lun->sync_interval)) { lun->sync_count = 0; mtx_unlock(&ctl_softc->ctl_lock); retval = lun->backend->config_write((union ctl_io *)ctsio); } else { mtx_unlock(&ctl_softc->ctl_lock); ctl_set_success(ctsio); ctl_done((union ctl_io *)ctsio); } bailout: return (retval); } int ctl_format(struct ctl_scsiio *ctsio) { struct scsi_format *cdb; struct ctl_lun *lun; struct ctl_softc *ctl_softc; int length, defect_list_len; CTL_DEBUG_PRINT(("ctl_format\n")); lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; ctl_softc = control_softc; cdb = (struct scsi_format *)ctsio->cdb; length = 0; if (cdb->byte2 & SF_FMTDATA) { if (cdb->byte2 & SF_LONGLIST) length = sizeof(struct scsi_format_header_long); else length = sizeof(struct scsi_format_header_short); } if (((ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) == 0) && (length > 0)) { ctsio->kern_data_ptr = malloc(length, M_CTL, M_WAITOK); if (ctsio->kern_data_ptr == NULL) { ctsio->io_hdr.status = CTL_SCSI_ERROR; ctsio->io_hdr.status = SCSI_STATUS_BUSY; ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } ctsio->kern_data_len = length; ctsio->kern_total_len = length; ctsio->kern_data_resid = 0; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } defect_list_len = 0; if (cdb->byte2 & SF_FMTDATA) { if (cdb->byte2 & SF_LONGLIST) { struct scsi_format_header_long *header; header = (struct scsi_format_header_long *) ctsio->kern_data_ptr; defect_list_len = scsi_4btoul(header->defect_list_len); if (defect_list_len != 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ 2, /*bit_valid*/ 0, /*bit*/ 0); goto bailout; } } else { struct scsi_format_header_short *header; header = (struct scsi_format_header_short *) ctsio->kern_data_ptr; defect_list_len = scsi_2btoul(header->defect_list_len); if (defect_list_len != 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ 2, /*bit_valid*/ 0, /*bit*/ 0); goto bailout; } } } /* * The format command will clear out the "Medium format corrupted" * status if set by the configuration code. That status is really * just a way to notify the host that we have lost the media, and * get them to issue a command that will basically make them think * they're blowing away the media. */ mtx_lock(&ctl_softc->ctl_lock); lun->flags &= ~CTL_LUN_INOPERABLE; mtx_unlock(&ctl_softc->ctl_lock); ctsio->scsi_status = SCSI_STATUS_OK; ctsio->io_hdr.status = CTL_SUCCESS; bailout: if (ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) { free(ctsio->kern_data_ptr, M_CTL); ctsio->io_hdr.flags &= ~CTL_FLAG_ALLOCATED; } ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_write_buffer(struct ctl_scsiio *ctsio) { struct scsi_write_buffer *cdb; struct copan_page_header *header; struct ctl_lun *lun; struct ctl_softc *ctl_softc; int buffer_offset, len; int retval; header = NULL; retval = CTL_RETVAL_COMPLETE; CTL_DEBUG_PRINT(("ctl_write_buffer\n")); lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; ctl_softc = control_softc; cdb = (struct scsi_write_buffer *)ctsio->cdb; if ((cdb->byte2 & RWB_MODE) != RWB_MODE_DATA) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 1, /*bit_valid*/ 1, /*bit*/ 4); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } if (cdb->buffer_id != 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } len = scsi_3btoul(cdb->length); buffer_offset = scsi_3btoul(cdb->offset); if (len > sizeof(lun->write_buffer)) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 6, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } if (buffer_offset != 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 3, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * If we've got a kernel request that hasn't been malloced yet, * malloc it and tell the caller the data buffer is here. */ if ((ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) == 0) { ctsio->kern_data_ptr = lun->write_buffer; ctsio->kern_data_len = len; ctsio->kern_total_len = len; ctsio->kern_data_resid = 0; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * Note that this function currently doesn't actually do anything inside * CTL to enforce things if the DQue bit is turned on. * * Also note that this function can't be used in the default case, because * the DQue bit isn't set in the changeable mask for the control mode page * anyway. This is just here as an example for how to implement a page * handler, and a placeholder in case we want to allow the user to turn * tagged queueing on and off. * * The D_SENSE bit handling is functional, however, and will turn * descriptor sense on and off for a given LUN. */ int ctl_control_page_handler(struct ctl_scsiio *ctsio, struct ctl_page_index *page_index, uint8_t *page_ptr) { struct scsi_control_page *current_cp, *saved_cp, *user_cp; struct ctl_lun *lun; struct ctl_softc *softc; int set_ua; uint32_t initidx; lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; initidx = ctl_get_initindex(&ctsio->io_hdr.nexus); set_ua = 0; user_cp = (struct scsi_control_page *)page_ptr; current_cp = (struct scsi_control_page *) (page_index->page_data + (page_index->page_len * CTL_PAGE_CURRENT)); saved_cp = (struct scsi_control_page *) (page_index->page_data + (page_index->page_len * CTL_PAGE_SAVED)); softc = control_softc; mtx_lock(&softc->ctl_lock); if (((current_cp->rlec & SCP_DSENSE) == 0) && ((user_cp->rlec & SCP_DSENSE) != 0)) { /* * Descriptor sense is currently turned off and the user * wants to turn it on. */ current_cp->rlec |= SCP_DSENSE; saved_cp->rlec |= SCP_DSENSE; lun->flags |= CTL_LUN_SENSE_DESC; set_ua = 1; } else if (((current_cp->rlec & SCP_DSENSE) != 0) && ((user_cp->rlec & SCP_DSENSE) == 0)) { /* * Descriptor sense is currently turned on, and the user * wants to turn it off. */ current_cp->rlec &= ~SCP_DSENSE; saved_cp->rlec &= ~SCP_DSENSE; lun->flags &= ~CTL_LUN_SENSE_DESC; set_ua = 1; } if (current_cp->queue_flags & SCP_QUEUE_DQUE) { if (user_cp->queue_flags & SCP_QUEUE_DQUE) { #ifdef NEEDTOPORT csevent_log(CSC_CTL | CSC_SHELF_SW | CTL_UNTAG_TO_UNTAG, csevent_LogType_Trace, csevent_Severity_Information, csevent_AlertLevel_Green, csevent_FRU_Firmware, csevent_FRU_Unknown, "Received untagged to untagged transition"); #endif /* NEEDTOPORT */ } else { #ifdef NEEDTOPORT csevent_log(CSC_CTL | CSC_SHELF_SW | CTL_UNTAG_TO_TAG, csevent_LogType_ConfigChange, csevent_Severity_Information, csevent_AlertLevel_Green, csevent_FRU_Firmware, csevent_FRU_Unknown, "Received untagged to tagged " "queueing transition"); #endif /* NEEDTOPORT */ current_cp->queue_flags &= ~SCP_QUEUE_DQUE; saved_cp->queue_flags &= ~SCP_QUEUE_DQUE; set_ua = 1; } } else { if (user_cp->queue_flags & SCP_QUEUE_DQUE) { #ifdef NEEDTOPORT csevent_log(CSC_CTL | CSC_SHELF_SW | CTL_TAG_TO_UNTAG, csevent_LogType_ConfigChange, csevent_Severity_Warning, csevent_AlertLevel_Yellow, csevent_FRU_Firmware, csevent_FRU_Unknown, "Received tagged queueing to untagged " "transition"); #endif /* NEEDTOPORT */ current_cp->queue_flags |= SCP_QUEUE_DQUE; saved_cp->queue_flags |= SCP_QUEUE_DQUE; set_ua = 1; } else { #ifdef NEEDTOPORT csevent_log(CSC_CTL | CSC_SHELF_SW | CTL_TAG_TO_TAG, csevent_LogType_Trace, csevent_Severity_Information, csevent_AlertLevel_Green, csevent_FRU_Firmware, csevent_FRU_Unknown, "Received tagged queueing to tagged " "queueing transition"); #endif /* NEEDTOPORT */ } } if (set_ua != 0) { int i; /* * Let other initiators know that the mode * parameters for this LUN have changed. */ for (i = 0; i < CTL_MAX_INITIATORS; i++) { if (i == initidx) continue; lun->pending_sense[i].ua_pending |= CTL_UA_MODE_CHANGE; } } mtx_unlock(&softc->ctl_lock); return (0); } int ctl_power_sp_handler(struct ctl_scsiio *ctsio, struct ctl_page_index *page_index, uint8_t *page_ptr) { return (0); } int ctl_power_sp_sense_handler(struct ctl_scsiio *ctsio, struct ctl_page_index *page_index, int pc) { struct copan_power_subpage *page; page = (struct copan_power_subpage *)page_index->page_data + (page_index->page_len * pc); switch (pc) { case SMS_PAGE_CTRL_CHANGEABLE >> 6: /* * We don't update the changable bits for this page. */ break; case SMS_PAGE_CTRL_CURRENT >> 6: case SMS_PAGE_CTRL_DEFAULT >> 6: case SMS_PAGE_CTRL_SAVED >> 6: #ifdef NEEDTOPORT ctl_update_power_subpage(page); #endif break; default: #ifdef NEEDTOPORT EPRINT(0, "Invalid PC %d!!", pc); #endif break; } return (0); } int ctl_aps_sp_handler(struct ctl_scsiio *ctsio, struct ctl_page_index *page_index, uint8_t *page_ptr) { struct copan_aps_subpage *user_sp; struct copan_aps_subpage *current_sp; union ctl_modepage_info *modepage_info; struct ctl_softc *softc; struct ctl_lun *lun; int retval; retval = CTL_RETVAL_COMPLETE; current_sp = (struct copan_aps_subpage *)(page_index->page_data + (page_index->page_len * CTL_PAGE_CURRENT)); softc = control_softc; lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; user_sp = (struct copan_aps_subpage *)page_ptr; modepage_info = (union ctl_modepage_info *) ctsio->io_hdr.ctl_private[CTL_PRIV_MODEPAGE].bytes; modepage_info->header.page_code = page_index->page_code & SMPH_PC_MASK; modepage_info->header.subpage = page_index->subpage; modepage_info->aps.lock_active = user_sp->lock_active; mtx_lock(&softc->ctl_lock); /* * If there is a request to lock the LUN and another LUN is locked * this is an error. If the requested LUN is already locked ignore * the request. If no LUN is locked attempt to lock it. * if there is a request to unlock the LUN and the LUN is currently * locked attempt to unlock it. Otherwise ignore the request. i.e. * if another LUN is locked or no LUN is locked. */ if (user_sp->lock_active & APS_LOCK_ACTIVE) { if (softc->aps_locked_lun == lun->lun) { /* * This LUN is already locked, so we're done. */ retval = CTL_RETVAL_COMPLETE; } else if (softc->aps_locked_lun == 0) { /* * No one has the lock, pass the request to the * backend. */ retval = lun->backend->config_write( (union ctl_io *)ctsio); } else { /* * Someone else has the lock, throw out the request. */ ctl_set_already_locked(ctsio); free(ctsio->kern_data_ptr, M_CTL); ctl_done((union ctl_io *)ctsio); /* * Set the return value so that ctl_do_mode_select() * won't try to complete the command. We already * completed it here. */ retval = CTL_RETVAL_ERROR; } } else if (softc->aps_locked_lun == lun->lun) { /* * This LUN is locked, so pass the unlock request to the * backend. */ retval = lun->backend->config_write((union ctl_io *)ctsio); } mtx_unlock(&softc->ctl_lock); return (retval); } int ctl_debugconf_sp_select_handler(struct ctl_scsiio *ctsio, struct ctl_page_index *page_index, uint8_t *page_ptr) { uint8_t *c; int i; c = ((struct copan_debugconf_subpage *)page_ptr)->ctl_time_io_secs; ctl_time_io_secs = (c[0] << 8) | (c[1] << 0) | 0; CTL_DEBUG_PRINT(("set ctl_time_io_secs to %d\n", ctl_time_io_secs)); printf("set ctl_time_io_secs to %d\n", ctl_time_io_secs); printf("page data:"); for (i=0; i<8; i++) printf(" %.2x",page_ptr[i]); printf("\n"); return (0); } int ctl_debugconf_sp_sense_handler(struct ctl_scsiio *ctsio, struct ctl_page_index *page_index, int pc) { struct copan_debugconf_subpage *page; page = (struct copan_debugconf_subpage *)page_index->page_data + (page_index->page_len * pc); switch (pc) { case SMS_PAGE_CTRL_CHANGEABLE >> 6: case SMS_PAGE_CTRL_DEFAULT >> 6: case SMS_PAGE_CTRL_SAVED >> 6: /* * We don't update the changable or default bits for this page. */ break; case SMS_PAGE_CTRL_CURRENT >> 6: page->ctl_time_io_secs[0] = ctl_time_io_secs >> 8; page->ctl_time_io_secs[1] = ctl_time_io_secs >> 0; break; default: #ifdef NEEDTOPORT EPRINT(0, "Invalid PC %d!!", pc); #endif /* NEEDTOPORT */ break; } return (0); } static int ctl_do_mode_select(union ctl_io *io) { struct scsi_mode_page_header *page_header; struct ctl_page_index *page_index; struct ctl_scsiio *ctsio; int control_dev, page_len; int page_len_offset, page_len_size; union ctl_modepage_info *modepage_info; struct ctl_lun *lun; int *len_left, *len_used; int retval, i; ctsio = &io->scsiio; page_index = NULL; page_len = 0; retval = CTL_RETVAL_COMPLETE; lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; if (lun->be_lun->lun_type != T_DIRECT) control_dev = 1; else control_dev = 0; modepage_info = (union ctl_modepage_info *) ctsio->io_hdr.ctl_private[CTL_PRIV_MODEPAGE].bytes; len_left = &modepage_info->header.len_left; len_used = &modepage_info->header.len_used; do_next_page: page_header = (struct scsi_mode_page_header *) (ctsio->kern_data_ptr + *len_used); if (*len_left == 0) { free(ctsio->kern_data_ptr, M_CTL); ctl_set_success(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } else if (*len_left < sizeof(struct scsi_mode_page_header)) { free(ctsio->kern_data_ptr, M_CTL); ctl_set_param_len_error(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } else if ((page_header->page_code & SMPH_SPF) && (*len_left < sizeof(struct scsi_mode_page_header_sp))) { free(ctsio->kern_data_ptr, M_CTL); ctl_set_param_len_error(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * XXX KDM should we do something with the block descriptor? */ for (i = 0; i < CTL_NUM_MODE_PAGES; i++) { if ((control_dev != 0) && (lun->mode_pages.index[i].page_flags & CTL_PAGE_FLAG_DISK_ONLY)) continue; if ((lun->mode_pages.index[i].page_code & SMPH_PC_MASK) != (page_header->page_code & SMPH_PC_MASK)) continue; /* * If neither page has a subpage code, then we've got a * match. */ if (((lun->mode_pages.index[i].page_code & SMPH_SPF) == 0) && ((page_header->page_code & SMPH_SPF) == 0)) { page_index = &lun->mode_pages.index[i]; page_len = page_header->page_length; break; } /* * If both pages have subpages, then the subpage numbers * have to match. */ if ((lun->mode_pages.index[i].page_code & SMPH_SPF) && (page_header->page_code & SMPH_SPF)) { struct scsi_mode_page_header_sp *sph; sph = (struct scsi_mode_page_header_sp *)page_header; if (lun->mode_pages.index[i].subpage == sph->subpage) { page_index = &lun->mode_pages.index[i]; page_len = scsi_2btoul(sph->page_length); break; } } } /* * If we couldn't find the page, or if we don't have a mode select * handler for it, send back an error to the user. */ if ((page_index == NULL) || (page_index->select_handler == NULL)) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ *len_used, /*bit_valid*/ 0, /*bit*/ 0); free(ctsio->kern_data_ptr, M_CTL); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } if (page_index->page_code & SMPH_SPF) { page_len_offset = 2; page_len_size = 2; } else { page_len_size = 1; page_len_offset = 1; } /* * If the length the initiator gives us isn't the one we specify in * the mode page header, or if they didn't specify enough data in * the CDB to avoid truncating this page, kick out the request. */ if ((page_len != (page_index->page_len - page_len_offset - page_len_size)) || (*len_left < page_index->page_len)) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ *len_used + page_len_offset, /*bit_valid*/ 0, /*bit*/ 0); free(ctsio->kern_data_ptr, M_CTL); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * Run through the mode page, checking to make sure that the bits * the user changed are actually legal for him to change. */ for (i = 0; i < page_index->page_len; i++) { uint8_t *user_byte, *change_mask, *current_byte; int bad_bit; int j; user_byte = (uint8_t *)page_header + i; change_mask = page_index->page_data + (page_index->page_len * CTL_PAGE_CHANGEABLE) + i; current_byte = page_index->page_data + (page_index->page_len * CTL_PAGE_CURRENT) + i; /* * Check to see whether the user set any bits in this byte * that he is not allowed to set. */ if ((*user_byte & ~(*change_mask)) == (*current_byte & ~(*change_mask))) continue; /* * Go through bit by bit to determine which one is illegal. */ bad_bit = 0; for (j = 7; j >= 0; j--) { if ((((1 << i) & ~(*change_mask)) & *user_byte) != (((1 << i) & ~(*change_mask)) & *current_byte)) { bad_bit = i; break; } } ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ *len_used + i, /*bit_valid*/ 1, /*bit*/ bad_bit); free(ctsio->kern_data_ptr, M_CTL); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * Decrement these before we call the page handler, since we may * end up getting called back one way or another before the handler * returns to this context. */ *len_left -= page_index->page_len; *len_used += page_index->page_len; retval = page_index->select_handler(ctsio, page_index, (uint8_t *)page_header); /* * If the page handler returns CTL_RETVAL_QUEUED, then we need to * wait until this queued command completes to finish processing * the mode page. If it returns anything other than * CTL_RETVAL_COMPLETE (e.g. CTL_RETVAL_ERROR), then it should have * already set the sense information, freed the data pointer, and * completed the io for us. */ if (retval != CTL_RETVAL_COMPLETE) goto bailout_no_done; /* * If the initiator sent us more than one page, parse the next one. */ if (*len_left > 0) goto do_next_page; ctl_set_success(ctsio); free(ctsio->kern_data_ptr, M_CTL); ctl_done((union ctl_io *)ctsio); bailout_no_done: return (CTL_RETVAL_COMPLETE); } int ctl_mode_select(struct ctl_scsiio *ctsio) { int param_len, pf, sp; int header_size, bd_len; int len_left, len_used; struct ctl_page_index *page_index; struct ctl_lun *lun; int control_dev, page_len; union ctl_modepage_info *modepage_info; int retval; pf = 0; sp = 0; page_len = 0; len_used = 0; len_left = 0; retval = 0; bd_len = 0; page_index = NULL; lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; if (lun->be_lun->lun_type != T_DIRECT) control_dev = 1; else control_dev = 0; switch (ctsio->cdb[0]) { case MODE_SELECT_6: { struct scsi_mode_select_6 *cdb; cdb = (struct scsi_mode_select_6 *)ctsio->cdb; pf = (cdb->byte2 & SMS_PF) ? 1 : 0; sp = (cdb->byte2 & SMS_SP) ? 1 : 0; param_len = cdb->length; header_size = sizeof(struct scsi_mode_header_6); break; } case MODE_SELECT_10: { struct scsi_mode_select_10 *cdb; cdb = (struct scsi_mode_select_10 *)ctsio->cdb; pf = (cdb->byte2 & SMS_PF) ? 1 : 0; sp = (cdb->byte2 & SMS_SP) ? 1 : 0; param_len = scsi_2btoul(cdb->length); header_size = sizeof(struct scsi_mode_header_10); break; } default: ctl_set_invalid_opcode(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); break; /* NOTREACHED */ } /* * From SPC-3: * "A parameter list length of zero indicates that the Data-Out Buffer * shall be empty. This condition shall not be considered as an error." */ if (param_len == 0) { ctl_set_success(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * Since we'll hit this the first time through, prior to * allocation, we don't need to free a data buffer here. */ if (param_len < header_size) { ctl_set_param_len_error(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * Allocate the data buffer and grab the user's data. In theory, * we shouldn't have to sanity check the parameter list length here * because the maximum size is 64K. We should be able to malloc * that much without too many problems. */ if ((ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) == 0) { ctsio->kern_data_ptr = malloc(param_len, M_CTL, M_WAITOK); if (ctsio->kern_data_ptr == NULL) { ctl_set_busy(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } ctsio->kern_data_len = param_len; ctsio->kern_total_len = param_len; ctsio->kern_data_resid = 0; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } switch (ctsio->cdb[0]) { case MODE_SELECT_6: { struct scsi_mode_header_6 *mh6; mh6 = (struct scsi_mode_header_6 *)ctsio->kern_data_ptr; bd_len = mh6->blk_desc_len; break; } case MODE_SELECT_10: { struct scsi_mode_header_10 *mh10; mh10 = (struct scsi_mode_header_10 *)ctsio->kern_data_ptr; bd_len = scsi_2btoul(mh10->blk_desc_len); break; } default: panic("Invalid CDB type %#x", ctsio->cdb[0]); break; } if (param_len < (header_size + bd_len)) { free(ctsio->kern_data_ptr, M_CTL); ctl_set_param_len_error(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * Set the IO_CONT flag, so that if this I/O gets passed to * ctl_config_write_done(), it'll get passed back to * ctl_do_mode_select() for further processing, or completion if * we're all done. */ ctsio->io_hdr.flags |= CTL_FLAG_IO_CONT; ctsio->io_cont = ctl_do_mode_select; modepage_info = (union ctl_modepage_info *) ctsio->io_hdr.ctl_private[CTL_PRIV_MODEPAGE].bytes; memset(modepage_info, 0, sizeof(*modepage_info)); len_left = param_len - header_size - bd_len; len_used = header_size + bd_len; modepage_info->header.len_left = len_left; modepage_info->header.len_used = len_used; return (ctl_do_mode_select((union ctl_io *)ctsio)); } int ctl_mode_sense(struct ctl_scsiio *ctsio) { struct ctl_lun *lun; int pc, page_code, dbd, llba, subpage; int alloc_len, page_len, header_len, total_len; struct scsi_mode_block_descr *block_desc; struct ctl_page_index *page_index; int control_dev; dbd = 0; llba = 0; block_desc = NULL; page_index = NULL; CTL_DEBUG_PRINT(("ctl_mode_sense\n")); lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; if (lun->be_lun->lun_type != T_DIRECT) control_dev = 1; else control_dev = 0; switch (ctsio->cdb[0]) { case MODE_SENSE_6: { struct scsi_mode_sense_6 *cdb; cdb = (struct scsi_mode_sense_6 *)ctsio->cdb; header_len = sizeof(struct scsi_mode_hdr_6); if (cdb->byte2 & SMS_DBD) dbd = 1; else header_len += sizeof(struct scsi_mode_block_descr); pc = (cdb->page & SMS_PAGE_CTRL_MASK) >> 6; page_code = cdb->page & SMS_PAGE_CODE; subpage = cdb->subpage; alloc_len = cdb->length; break; } case MODE_SENSE_10: { struct scsi_mode_sense_10 *cdb; cdb = (struct scsi_mode_sense_10 *)ctsio->cdb; header_len = sizeof(struct scsi_mode_hdr_10); if (cdb->byte2 & SMS_DBD) dbd = 1; else header_len += sizeof(struct scsi_mode_block_descr); if (cdb->byte2 & SMS10_LLBAA) llba = 1; pc = (cdb->page & SMS_PAGE_CTRL_MASK) >> 6; page_code = cdb->page & SMS_PAGE_CODE; subpage = cdb->subpage; alloc_len = scsi_2btoul(cdb->length); break; } default: ctl_set_invalid_opcode(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); break; /* NOTREACHED */ } /* * We have to make a first pass through to calculate the size of * the pages that match the user's query. Then we allocate enough * memory to hold it, and actually copy the data into the buffer. */ switch (page_code) { case SMS_ALL_PAGES_PAGE: { int i; page_len = 0; /* * At the moment, values other than 0 and 0xff here are * reserved according to SPC-3. */ if ((subpage != SMS_SUBPAGE_PAGE_0) && (subpage != SMS_SUBPAGE_ALL)) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 3, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } for (i = 0; i < CTL_NUM_MODE_PAGES; i++) { if ((control_dev != 0) && (lun->mode_pages.index[i].page_flags & CTL_PAGE_FLAG_DISK_ONLY)) continue; /* * We don't use this subpage if the user didn't * request all subpages. */ if ((lun->mode_pages.index[i].subpage != 0) && (subpage == SMS_SUBPAGE_PAGE_0)) continue; #if 0 printf("found page %#x len %d\n", lun->mode_pages.index[i].page_code & SMPH_PC_MASK, lun->mode_pages.index[i].page_len); #endif page_len += lun->mode_pages.index[i].page_len; } break; } default: { int i; page_len = 0; for (i = 0; i < CTL_NUM_MODE_PAGES; i++) { /* Look for the right page code */ if ((lun->mode_pages.index[i].page_code & SMPH_PC_MASK) != page_code) continue; /* Look for the right subpage or the subpage wildcard*/ if ((lun->mode_pages.index[i].subpage != subpage) && (subpage != SMS_SUBPAGE_ALL)) continue; /* Make sure the page is supported for this dev type */ if ((control_dev != 0) && (lun->mode_pages.index[i].page_flags & CTL_PAGE_FLAG_DISK_ONLY)) continue; #if 0 printf("found page %#x len %d\n", lun->mode_pages.index[i].page_code & SMPH_PC_MASK, lun->mode_pages.index[i].page_len); #endif page_len += lun->mode_pages.index[i].page_len; } if (page_len == 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 1, /*bit*/ 5); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } break; } } total_len = header_len + page_len; #if 0 printf("header_len = %d, page_len = %d, total_len = %d\n", header_len, page_len, total_len); #endif ctsio->kern_data_ptr = malloc(total_len, M_CTL, M_WAITOK); if (ctsio->kern_data_ptr == NULL) { ctsio->io_hdr.status = CTL_SCSI_ERROR; ctsio->scsi_status = SCSI_STATUS_BUSY; ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } ctsio->kern_sg_entries = 0; ctsio->kern_data_resid = 0; ctsio->kern_rel_offset = 0; if (total_len < alloc_len) { ctsio->residual = alloc_len - total_len; ctsio->kern_data_len = total_len; ctsio->kern_total_len = total_len; } else { ctsio->residual = 0; ctsio->kern_data_len = alloc_len; ctsio->kern_total_len = alloc_len; } memset(ctsio->kern_data_ptr, 0, total_len); switch (ctsio->cdb[0]) { case MODE_SENSE_6: { struct scsi_mode_hdr_6 *header; header = (struct scsi_mode_hdr_6 *)ctsio->kern_data_ptr; header->datalen = ctl_min(total_len - 1, 254); if (dbd) header->block_descr_len = 0; else header->block_descr_len = sizeof(struct scsi_mode_block_descr); block_desc = (struct scsi_mode_block_descr *)&header[1]; break; } case MODE_SENSE_10: { struct scsi_mode_hdr_10 *header; int datalen; header = (struct scsi_mode_hdr_10 *)ctsio->kern_data_ptr; datalen = ctl_min(total_len - 2, 65533); scsi_ulto2b(datalen, header->datalen); if (dbd) scsi_ulto2b(0, header->block_descr_len); else scsi_ulto2b(sizeof(struct scsi_mode_block_descr), header->block_descr_len); block_desc = (struct scsi_mode_block_descr *)&header[1]; break; } default: panic("invalid CDB type %#x", ctsio->cdb[0]); break; /* NOTREACHED */ } /* * If we've got a disk, use its blocksize in the block * descriptor. Otherwise, just set it to 0. */ if (dbd == 0) { if (control_dev != 0) scsi_ulto3b(lun->be_lun->blocksize, block_desc->block_len); else scsi_ulto3b(0, block_desc->block_len); } switch (page_code) { case SMS_ALL_PAGES_PAGE: { int i, data_used; data_used = header_len; for (i = 0; i < CTL_NUM_MODE_PAGES; i++) { struct ctl_page_index *page_index; page_index = &lun->mode_pages.index[i]; if ((control_dev != 0) && (page_index->page_flags & CTL_PAGE_FLAG_DISK_ONLY)) continue; /* * We don't use this subpage if the user didn't * request all subpages. We already checked (above) * to make sure the user only specified a subpage * of 0 or 0xff in the SMS_ALL_PAGES_PAGE case. */ if ((page_index->subpage != 0) && (subpage == SMS_SUBPAGE_PAGE_0)) continue; /* * Call the handler, if it exists, to update the * page to the latest values. */ if (page_index->sense_handler != NULL) page_index->sense_handler(ctsio, page_index,pc); memcpy(ctsio->kern_data_ptr + data_used, page_index->page_data + (page_index->page_len * pc), page_index->page_len); data_used += page_index->page_len; } break; } default: { int i, data_used; data_used = header_len; for (i = 0; i < CTL_NUM_MODE_PAGES; i++) { struct ctl_page_index *page_index; page_index = &lun->mode_pages.index[i]; /* Look for the right page code */ if ((page_index->page_code & SMPH_PC_MASK) != page_code) continue; /* Look for the right subpage or the subpage wildcard*/ if ((page_index->subpage != subpage) && (subpage != SMS_SUBPAGE_ALL)) continue; /* Make sure the page is supported for this dev type */ if ((control_dev != 0) && (page_index->page_flags & CTL_PAGE_FLAG_DISK_ONLY)) continue; /* * Call the handler, if it exists, to update the * page to the latest values. */ if (page_index->sense_handler != NULL) page_index->sense_handler(ctsio, page_index,pc); memcpy(ctsio->kern_data_ptr + data_used, page_index->page_data + (page_index->page_len * pc), page_index->page_len); data_used += page_index->page_len; } break; } } ctsio->scsi_status = SCSI_STATUS_OK; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_read_capacity(struct ctl_scsiio *ctsio) { struct scsi_read_capacity *cdb; struct scsi_read_capacity_data *data; struct ctl_lun *lun; uint32_t lba; CTL_DEBUG_PRINT(("ctl_read_capacity\n")); cdb = (struct scsi_read_capacity *)ctsio->cdb; lba = scsi_4btoul(cdb->addr); if (((cdb->pmi & SRC_PMI) == 0) && (lba != 0)) { ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; ctsio->kern_data_ptr = malloc(sizeof(*data), M_CTL, M_WAITOK); if (ctsio->kern_data_ptr == NULL) { ctsio->io_hdr.status = CTL_SCSI_ERROR; ctsio->scsi_status = SCSI_STATUS_BUSY; ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } data = (struct scsi_read_capacity_data *)ctsio->kern_data_ptr; ctsio->residual = 0; ctsio->kern_data_len = sizeof(*data); ctsio->kern_total_len = sizeof(*data); ctsio->kern_data_resid = 0; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; memset(data, 0, sizeof(*data)); /* * If the maximum LBA is greater than 0xfffffffe, the user must * issue a SERVICE ACTION IN (16) command, with the read capacity * serivce action set. */ if (lun->be_lun->maxlba > 0xfffffffe) scsi_ulto4b(0xffffffff, data->addr); else scsi_ulto4b(lun->be_lun->maxlba, data->addr); /* * XXX KDM this may not be 512 bytes... */ scsi_ulto4b(lun->be_lun->blocksize, data->length); ctsio->scsi_status = SCSI_STATUS_OK; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } static int ctl_read_capacity_16(struct ctl_scsiio *ctsio) { struct scsi_read_capacity_16 *cdb; struct scsi_read_capacity_data_long *data; struct ctl_lun *lun; uint64_t lba; uint32_t alloc_len; CTL_DEBUG_PRINT(("ctl_read_capacity_16\n")); cdb = (struct scsi_read_capacity_16 *)ctsio->cdb; alloc_len = scsi_4btoul(cdb->alloc_len); lba = scsi_8btou64(cdb->addr); if ((cdb->reladr & SRC16_PMI) && (lba != 0)) { ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; ctsio->kern_data_ptr = malloc(sizeof(*data), M_CTL, M_WAITOK); if (ctsio->kern_data_ptr == NULL) { ctsio->io_hdr.status = CTL_SCSI_ERROR; ctsio->scsi_status = SCSI_STATUS_BUSY; ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } data = (struct scsi_read_capacity_data_long *)ctsio->kern_data_ptr; if (sizeof(*data) < alloc_len) { ctsio->residual = alloc_len - sizeof(*data); ctsio->kern_data_len = sizeof(*data); ctsio->kern_total_len = sizeof(*data); } else { ctsio->residual = 0; ctsio->kern_data_len = alloc_len; ctsio->kern_total_len = alloc_len; } ctsio->kern_data_resid = 0; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; memset(data, 0, sizeof(*data)); scsi_u64to8b(lun->be_lun->maxlba, data->addr); /* XXX KDM this may not be 512 bytes... */ scsi_ulto4b(lun->be_lun->blocksize, data->length); ctsio->scsi_status = SCSI_STATUS_OK; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_service_action_in(struct ctl_scsiio *ctsio) { struct scsi_service_action_in *cdb; int retval; CTL_DEBUG_PRINT(("ctl_service_action_in\n")); cdb = (struct scsi_service_action_in *)ctsio->cdb; retval = CTL_RETVAL_COMPLETE; switch (cdb->service_action) { case SRC16_SERVICE_ACTION: retval = ctl_read_capacity_16(ctsio); break; default: ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 1, /*bit_valid*/ 1, /*bit*/ 4); ctl_done((union ctl_io *)ctsio); break; } return (retval); } int ctl_maintenance_in(struct ctl_scsiio *ctsio) { struct scsi_maintenance_in *cdb; int retval; int alloc_len, total_len = 0; int num_target_port_groups; struct ctl_lun *lun; struct ctl_softc *softc; struct scsi_target_group_data *rtg_ptr; struct scsi_target_port_group_descriptor *tpg_desc_ptr1, *tpg_desc_ptr2; struct scsi_target_port_descriptor *tp_desc_ptr1_1, *tp_desc_ptr1_2, *tp_desc_ptr2_1, *tp_desc_ptr2_2; CTL_DEBUG_PRINT(("ctl_maintenance_in\n")); cdb = (struct scsi_maintenance_in *)ctsio->cdb; softc = control_softc; lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; retval = CTL_RETVAL_COMPLETE; mtx_lock(&softc->ctl_lock); if ((cdb->byte2 & SERVICE_ACTION_MASK) != SA_RPRT_TRGT_GRP) { ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 1, /*bit_valid*/ 1, /*bit*/ 4); ctl_done((union ctl_io *)ctsio); return(retval); } if (ctl_is_single) num_target_port_groups = NUM_TARGET_PORT_GROUPS - 1; else num_target_port_groups = NUM_TARGET_PORT_GROUPS; total_len = sizeof(struct scsi_target_group_data) + sizeof(struct scsi_target_port_group_descriptor) * num_target_port_groups + sizeof(struct scsi_target_port_descriptor) * NUM_PORTS_PER_GRP * num_target_port_groups; alloc_len = scsi_4btoul(cdb->length); ctsio->kern_data_ptr = malloc(total_len, M_CTL, M_WAITOK); if (ctsio->kern_data_ptr == NULL) { ctsio->io_hdr.status = CTL_SCSI_ERROR; ctsio->scsi_status = SCSI_STATUS_BUSY; ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } memset(ctsio->kern_data_ptr, 0, total_len); ctsio->kern_sg_entries = 0; if (total_len < alloc_len) { ctsio->residual = alloc_len - total_len; ctsio->kern_data_len = total_len; ctsio->kern_total_len = total_len; } else { ctsio->residual = 0; ctsio->kern_data_len = alloc_len; ctsio->kern_total_len = alloc_len; } ctsio->kern_data_resid = 0; ctsio->kern_rel_offset = 0; rtg_ptr = (struct scsi_target_group_data *)ctsio->kern_data_ptr; tpg_desc_ptr1 = &rtg_ptr->groups[0]; tp_desc_ptr1_1 = &tpg_desc_ptr1->descriptors[0]; tp_desc_ptr1_2 = (struct scsi_target_port_descriptor *) &tp_desc_ptr1_1->desc_list[0]; if (ctl_is_single == 0) { tpg_desc_ptr2 = (struct scsi_target_port_group_descriptor *) &tp_desc_ptr1_2->desc_list[0]; tp_desc_ptr2_1 = &tpg_desc_ptr2->descriptors[0]; tp_desc_ptr2_2 = (struct scsi_target_port_descriptor *) &tp_desc_ptr2_1->desc_list[0]; } else { tpg_desc_ptr2 = NULL; tp_desc_ptr2_1 = NULL; tp_desc_ptr2_2 = NULL; } scsi_ulto4b(total_len - 4, rtg_ptr->length); if (ctl_is_single == 0) { if (ctsio->io_hdr.nexus.targ_port < CTL_MAX_PORTS) { if (lun->flags & CTL_LUN_PRIMARY_SC) { tpg_desc_ptr1->pref_state = TPG_PRIMARY; tpg_desc_ptr2->pref_state = TPG_ASYMMETRIC_ACCESS_NONOPTIMIZED; } else { tpg_desc_ptr1->pref_state = TPG_ASYMMETRIC_ACCESS_NONOPTIMIZED; tpg_desc_ptr2->pref_state = TPG_PRIMARY; } } else { if (lun->flags & CTL_LUN_PRIMARY_SC) { tpg_desc_ptr1->pref_state = TPG_ASYMMETRIC_ACCESS_NONOPTIMIZED; tpg_desc_ptr2->pref_state = TPG_PRIMARY; } else { tpg_desc_ptr1->pref_state = TPG_PRIMARY; tpg_desc_ptr2->pref_state = TPG_ASYMMETRIC_ACCESS_NONOPTIMIZED; } } } else { tpg_desc_ptr1->pref_state = TPG_PRIMARY; } tpg_desc_ptr1->support = 0; tpg_desc_ptr1->target_port_group[1] = 1; tpg_desc_ptr1->status = TPG_IMPLICIT; tpg_desc_ptr1->target_port_count= NUM_PORTS_PER_GRP; if (ctl_is_single == 0) { tpg_desc_ptr2->support = 0; tpg_desc_ptr2->target_port_group[1] = 2; tpg_desc_ptr2->status = TPG_IMPLICIT; tpg_desc_ptr2->target_port_count = NUM_PORTS_PER_GRP; tp_desc_ptr1_1->relative_target_port_identifier[1] = 1; tp_desc_ptr1_2->relative_target_port_identifier[1] = 2; tp_desc_ptr2_1->relative_target_port_identifier[1] = 9; tp_desc_ptr2_2->relative_target_port_identifier[1] = 10; } else { if (ctsio->io_hdr.nexus.targ_port < CTL_MAX_PORTS) { tp_desc_ptr1_1->relative_target_port_identifier[1] = 1; tp_desc_ptr1_2->relative_target_port_identifier[1] = 2; } else { tp_desc_ptr1_1->relative_target_port_identifier[1] = 9; tp_desc_ptr1_2->relative_target_port_identifier[1] = 10; } } mtx_unlock(&softc->ctl_lock); ctsio->be_move_done = ctl_config_move_done; CTL_DEBUG_PRINT(("buf = %x %x %x %x %x %x %x %x\n", ctsio->kern_data_ptr[0], ctsio->kern_data_ptr[1], ctsio->kern_data_ptr[2], ctsio->kern_data_ptr[3], ctsio->kern_data_ptr[4], ctsio->kern_data_ptr[5], ctsio->kern_data_ptr[6], ctsio->kern_data_ptr[7])); ctl_datamove((union ctl_io *)ctsio); return(retval); } int ctl_persistent_reserve_in(struct ctl_scsiio *ctsio) { struct scsi_per_res_in *cdb; int alloc_len, total_len = 0; /* struct scsi_per_res_in_rsrv in_data; */ struct ctl_lun *lun; struct ctl_softc *softc; CTL_DEBUG_PRINT(("ctl_persistent_reserve_in\n")); softc = control_softc; cdb = (struct scsi_per_res_in *)ctsio->cdb; alloc_len = scsi_2btoul(cdb->length); lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; retry: mtx_lock(&softc->ctl_lock); switch (cdb->action) { case SPRI_RK: /* read keys */ total_len = sizeof(struct scsi_per_res_in_keys) + lun->pr_key_count * sizeof(struct scsi_per_res_key); break; case SPRI_RR: /* read reservation */ if (lun->flags & CTL_LUN_PR_RESERVED) total_len = sizeof(struct scsi_per_res_in_rsrv); else total_len = sizeof(struct scsi_per_res_in_header); break; case SPRI_RC: /* report capabilities */ total_len = sizeof(struct scsi_per_res_cap); break; case SPRI_RS: /* read full status */ default: mtx_unlock(&softc->ctl_lock); ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 1, /*bit_valid*/ 1, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); break; /* NOTREACHED */ } mtx_unlock(&softc->ctl_lock); ctsio->kern_data_ptr = malloc(total_len, M_CTL, M_WAITOK); if (ctsio->kern_data_ptr == NULL) { ctsio->io_hdr.status = CTL_SCSI_ERROR; ctsio->scsi_status = SCSI_STATUS_BUSY; ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } if (total_len < alloc_len) { ctsio->residual = alloc_len - total_len; ctsio->kern_data_len = total_len; ctsio->kern_total_len = total_len; } else { ctsio->residual = 0; ctsio->kern_data_len = alloc_len; ctsio->kern_total_len = alloc_len; } ctsio->kern_data_resid = 0; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; memset(ctsio->kern_data_ptr, 0, total_len); mtx_lock(&softc->ctl_lock); switch (cdb->action) { case SPRI_RK: { // read keys struct scsi_per_res_in_keys *res_keys; int i, key_count; res_keys = (struct scsi_per_res_in_keys*)ctsio->kern_data_ptr; /* * We had to drop the lock to allocate our buffer, which * leaves time for someone to come in with another * persistent reservation. (That is unlikely, though, * since this should be the only persistent reservation * command active right now.) */ if (total_len != (sizeof(struct scsi_per_res_in_keys) + (lun->pr_key_count * sizeof(struct scsi_per_res_key)))){ mtx_unlock(&softc->ctl_lock); free(ctsio->kern_data_ptr, M_CTL); printf("%s: reservation length changed, retrying\n", __func__); goto retry; } scsi_ulto4b(lun->PRGeneration, res_keys->header.generation); scsi_ulto4b(sizeof(struct scsi_per_res_key) * lun->pr_key_count, res_keys->header.length); for (i = 0, key_count = 0; i < 2*CTL_MAX_INITIATORS; i++) { if (!lun->per_res[i].registered) continue; /* * We used lun->pr_key_count to calculate the * size to allocate. If it turns out the number of * initiators with the registered flag set is * larger than that (i.e. they haven't been kept in * sync), we've got a problem. */ if (key_count >= lun->pr_key_count) { #ifdef NEEDTOPORT csevent_log(CSC_CTL | CSC_SHELF_SW | CTL_PR_ERROR, csevent_LogType_Fault, csevent_AlertLevel_Yellow, csevent_FRU_ShelfController, csevent_FRU_Firmware, csevent_FRU_Unknown, "registered keys %d >= key " "count %d", key_count, lun->pr_key_count); #endif key_count++; continue; } memcpy(res_keys->keys[key_count].key, lun->per_res[i].res_key.key, ctl_min(sizeof(res_keys->keys[key_count].key), sizeof(lun->per_res[i].res_key))); key_count++; } break; } case SPRI_RR: { // read reservation struct scsi_per_res_in_rsrv *res; int tmp_len, header_only; res = (struct scsi_per_res_in_rsrv *)ctsio->kern_data_ptr; scsi_ulto4b(lun->PRGeneration, res->header.generation); if (lun->flags & CTL_LUN_PR_RESERVED) { tmp_len = sizeof(struct scsi_per_res_in_rsrv); scsi_ulto4b(sizeof(struct scsi_per_res_in_rsrv_data), res->header.length); header_only = 0; } else { tmp_len = sizeof(struct scsi_per_res_in_header); scsi_ulto4b(0, res->header.length); header_only = 1; } /* * We had to drop the lock to allocate our buffer, which * leaves time for someone to come in with another * persistent reservation. (That is unlikely, though, * since this should be the only persistent reservation * command active right now.) */ if (tmp_len != total_len) { mtx_unlock(&softc->ctl_lock); free(ctsio->kern_data_ptr, M_CTL); printf("%s: reservation status changed, retrying\n", __func__); goto retry; } /* * No reservation held, so we're done. */ if (header_only != 0) break; /* * If the registration is an All Registrants type, the key * is 0, since it doesn't really matter. */ if (lun->pr_res_idx != CTL_PR_ALL_REGISTRANTS) { memcpy(res->data.reservation, &lun->per_res[lun->pr_res_idx].res_key, sizeof(struct scsi_per_res_key)); } res->data.scopetype = lun->res_type; break; } case SPRI_RC: //report capabilities { struct scsi_per_res_cap *res_cap; uint16_t type_mask; res_cap = (struct scsi_per_res_cap *)ctsio->kern_data_ptr; scsi_ulto2b(sizeof(*res_cap), res_cap->length); res_cap->flags2 |= SPRI_TMV; type_mask = SPRI_TM_WR_EX_AR | SPRI_TM_EX_AC_RO | SPRI_TM_WR_EX_RO | SPRI_TM_EX_AC | SPRI_TM_WR_EX | SPRI_TM_EX_AC_AR; scsi_ulto2b(type_mask, res_cap->type_mask); break; } case SPRI_RS: //read full status default: /* * This is a bug, because we just checked for this above, * and should have returned an error. */ panic("Invalid PR type %x", cdb->action); break; /* NOTREACHED */ } mtx_unlock(&softc->ctl_lock); ctsio->be_move_done = ctl_config_move_done; CTL_DEBUG_PRINT(("buf = %x %x %x %x %x %x %x %x\n", ctsio->kern_data_ptr[0], ctsio->kern_data_ptr[1], ctsio->kern_data_ptr[2], ctsio->kern_data_ptr[3], ctsio->kern_data_ptr[4], ctsio->kern_data_ptr[5], ctsio->kern_data_ptr[6], ctsio->kern_data_ptr[7])); ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * Returns 0 if ctl_persistent_reserve_out() should continue, non-zero if * it should return. */ static int ctl_pro_preempt(struct ctl_softc *softc, struct ctl_lun *lun, uint64_t res_key, uint64_t sa_res_key, uint8_t type, uint32_t residx, struct ctl_scsiio *ctsio, struct scsi_per_res_out *cdb, struct scsi_per_res_out_parms* param) { union ctl_ha_msg persis_io; int retval, i; int isc_retval; retval = 0; if (sa_res_key == 0) { mtx_lock(&softc->ctl_lock); if (lun->pr_res_idx == CTL_PR_ALL_REGISTRANTS) { /* validate scope and type */ if ((cdb->scope_type & SPR_SCOPE_MASK) != SPR_LU_SCOPE) { mtx_unlock(&softc->ctl_lock); ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 1, /*bit*/ 4); ctl_done((union ctl_io *)ctsio); return (1); } if (type>8 || type==2 || type==4 || type==0) { mtx_unlock(&softc->ctl_lock); ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 1, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (1); } /* temporarily unregister this nexus */ lun->per_res[residx].registered = 0; /* * Unregister everybody else and build UA for * them */ for(i=0; i < 2*CTL_MAX_INITIATORS; i++) { if (lun->per_res[i].registered == 0) continue; if (!persis_offset && i <CTL_MAX_INITIATORS) lun->pending_sense[i].ua_pending |= CTL_UA_REG_PREEMPT; else if (persis_offset && i >= persis_offset) lun->pending_sense[i-persis_offset ].ua_pending |= CTL_UA_REG_PREEMPT; lun->per_res[i].registered = 0; memset(&lun->per_res[i].res_key, 0, sizeof(struct scsi_per_res_key)); } lun->per_res[residx].registered = 1; lun->pr_key_count = 1; lun->res_type = type; if (lun->res_type != SPR_TYPE_WR_EX_AR && lun->res_type != SPR_TYPE_EX_AC_AR) lun->pr_res_idx = residx; mtx_unlock(&softc->ctl_lock); /* send msg to other side */ persis_io.hdr.nexus = ctsio->io_hdr.nexus; persis_io.hdr.msg_type = CTL_MSG_PERS_ACTION; persis_io.pr.pr_info.action = CTL_PR_PREEMPT; persis_io.pr.pr_info.residx = lun->pr_res_idx; persis_io.pr.pr_info.res_type = type; memcpy(persis_io.pr.pr_info.sa_res_key, param->serv_act_res_key, sizeof(param->serv_act_res_key)); if ((isc_retval=ctl_ha_msg_send(CTL_HA_CHAN_CTL, &persis_io, sizeof(persis_io), 0)) > CTL_HA_STATUS_SUCCESS) { printf("CTL:Persis Out error returned " "from ctl_ha_msg_send %d\n", isc_retval); } } else { /* not all registrants */ mtx_unlock(&softc->ctl_lock); free(ctsio->kern_data_ptr, M_CTL); ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ 8, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (1); } } else if (lun->pr_res_idx == CTL_PR_ALL_REGISTRANTS || !(lun->flags & CTL_LUN_PR_RESERVED)) { int found = 0; mtx_lock(&softc->ctl_lock); if (res_key == sa_res_key) { /* special case */ /* * The spec implies this is not good but doesn't * say what to do. There are two choices either * generate a res conflict or check condition * with illegal field in parameter data. Since * that is what is done when the sa_res_key is * zero I'll take that approach since this has * to do with the sa_res_key. */ mtx_unlock(&softc->ctl_lock); free(ctsio->kern_data_ptr, M_CTL); ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ 8, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (1); } for (i=0; i < 2*CTL_MAX_INITIATORS; i++) { if (lun->per_res[i].registered && memcmp(param->serv_act_res_key, lun->per_res[i].res_key.key, sizeof(struct scsi_per_res_key)) != 0) continue; found = 1; lun->per_res[i].registered = 0; memset(&lun->per_res[i].res_key, 0, sizeof(struct scsi_per_res_key)); lun->pr_key_count--; if (!persis_offset && i < CTL_MAX_INITIATORS) lun->pending_sense[i].ua_pending |= CTL_UA_REG_PREEMPT; else if (persis_offset && i >= persis_offset) lun->pending_sense[i-persis_offset].ua_pending|= CTL_UA_REG_PREEMPT; } mtx_unlock(&softc->ctl_lock); if (!found) { free(ctsio->kern_data_ptr, M_CTL); ctl_set_reservation_conflict(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* send msg to other side */ persis_io.hdr.nexus = ctsio->io_hdr.nexus; persis_io.hdr.msg_type = CTL_MSG_PERS_ACTION; persis_io.pr.pr_info.action = CTL_PR_PREEMPT; persis_io.pr.pr_info.residx = lun->pr_res_idx; persis_io.pr.pr_info.res_type = type; memcpy(persis_io.pr.pr_info.sa_res_key, param->serv_act_res_key, sizeof(param->serv_act_res_key)); if ((isc_retval=ctl_ha_msg_send(CTL_HA_CHAN_CTL, &persis_io, sizeof(persis_io), 0)) > CTL_HA_STATUS_SUCCESS) { printf("CTL:Persis Out error returned from " "ctl_ha_msg_send %d\n", isc_retval); } } else { /* Reserved but not all registrants */ /* sa_res_key is res holder */ if (memcmp(param->serv_act_res_key, lun->per_res[lun->pr_res_idx].res_key.key, sizeof(struct scsi_per_res_key)) == 0) { /* validate scope and type */ if ((cdb->scope_type & SPR_SCOPE_MASK) != SPR_LU_SCOPE) { ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 1, /*bit*/ 4); ctl_done((union ctl_io *)ctsio); return (1); } if (type>8 || type==2 || type==4 || type==0) { ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 1, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (1); } /* * Do the following: * if sa_res_key != res_key remove all * registrants w/sa_res_key and generate UA * for these registrants(Registrations * Preempted) if it wasn't an exclusive * reservation generate UA(Reservations * Preempted) for all other registered nexuses * if the type has changed. Establish the new * reservation and holder. If res_key and * sa_res_key are the same do the above * except don't unregister the res holder. */ /* * Temporarily unregister so it won't get * removed or UA generated */ lun->per_res[residx].registered = 0; for(i=0; i < 2*CTL_MAX_INITIATORS; i++) { if (lun->per_res[i].registered == 0) continue; if (memcmp(param->serv_act_res_key, lun->per_res[i].res_key.key, sizeof(struct scsi_per_res_key)) == 0) { lun->per_res[i].registered = 0; memset(&lun->per_res[i].res_key, 0, sizeof(struct scsi_per_res_key)); lun->pr_key_count--; if (!persis_offset && i < CTL_MAX_INITIATORS) lun->pending_sense[i ].ua_pending |= CTL_UA_REG_PREEMPT; else if (persis_offset && i >= persis_offset) lun->pending_sense[ i-persis_offset].ua_pending |= CTL_UA_REG_PREEMPT; } else if (type != lun->res_type && (lun->res_type == SPR_TYPE_WR_EX_RO || lun->res_type ==SPR_TYPE_EX_AC_RO)){ if (!persis_offset && i < CTL_MAX_INITIATORS) lun->pending_sense[i ].ua_pending |= CTL_UA_RES_RELEASE; else if (persis_offset && i >= persis_offset) lun->pending_sense[ i-persis_offset ].ua_pending |= CTL_UA_RES_RELEASE; } } lun->per_res[residx].registered = 1; lun->res_type = type; if (lun->res_type != SPR_TYPE_WR_EX_AR && lun->res_type != SPR_TYPE_EX_AC_AR) lun->pr_res_idx = residx; else lun->pr_res_idx = CTL_PR_ALL_REGISTRANTS; persis_io.hdr.nexus = ctsio->io_hdr.nexus; persis_io.hdr.msg_type = CTL_MSG_PERS_ACTION; persis_io.pr.pr_info.action = CTL_PR_PREEMPT; persis_io.pr.pr_info.residx = lun->pr_res_idx; persis_io.pr.pr_info.res_type = type; memcpy(persis_io.pr.pr_info.sa_res_key, param->serv_act_res_key, sizeof(param->serv_act_res_key)); if ((isc_retval=ctl_ha_msg_send(CTL_HA_CHAN_CTL, &persis_io, sizeof(persis_io), 0)) > CTL_HA_STATUS_SUCCESS) { printf("CTL:Persis Out error returned " "from ctl_ha_msg_send %d\n", isc_retval); } } else { /* * sa_res_key is not the res holder just * remove registrants */ int found=0; mtx_lock(&softc->ctl_lock); for (i=0; i < 2*CTL_MAX_INITIATORS; i++) { if (memcmp(param->serv_act_res_key, lun->per_res[i].res_key.key, sizeof(struct scsi_per_res_key)) != 0) continue; found = 1; lun->per_res[i].registered = 0; memset(&lun->per_res[i].res_key, 0, sizeof(struct scsi_per_res_key)); lun->pr_key_count--; if (!persis_offset && i < CTL_MAX_INITIATORS) lun->pending_sense[i].ua_pending |= CTL_UA_REG_PREEMPT; else if (persis_offset && i >= persis_offset) lun->pending_sense[ i-persis_offset].ua_pending |= CTL_UA_REG_PREEMPT; } if (!found) { mtx_unlock(&softc->ctl_lock); free(ctsio->kern_data_ptr, M_CTL); ctl_set_reservation_conflict(ctsio); ctl_done((union ctl_io *)ctsio); return (1); } mtx_unlock(&softc->ctl_lock); persis_io.hdr.nexus = ctsio->io_hdr.nexus; persis_io.hdr.msg_type = CTL_MSG_PERS_ACTION; persis_io.pr.pr_info.action = CTL_PR_PREEMPT; persis_io.pr.pr_info.residx = lun->pr_res_idx; persis_io.pr.pr_info.res_type = type; memcpy(persis_io.pr.pr_info.sa_res_key, param->serv_act_res_key, sizeof(param->serv_act_res_key)); if ((isc_retval=ctl_ha_msg_send(CTL_HA_CHAN_CTL, &persis_io, sizeof(persis_io), 0)) > CTL_HA_STATUS_SUCCESS) { printf("CTL:Persis Out error returned " "from ctl_ha_msg_send %d\n", isc_retval); } } } lun->PRGeneration++; return (retval); } static void ctl_pro_preempt_other(struct ctl_lun *lun, union ctl_ha_msg *msg) { int i; if (lun->pr_res_idx == CTL_PR_ALL_REGISTRANTS || lun->pr_res_idx == CTL_PR_NO_RESERVATION || memcmp(&lun->per_res[lun->pr_res_idx].res_key, msg->pr.pr_info.sa_res_key, sizeof(struct scsi_per_res_key)) != 0) { uint64_t sa_res_key; sa_res_key = scsi_8btou64(msg->pr.pr_info.sa_res_key); if (sa_res_key == 0) { /* temporarily unregister this nexus */ lun->per_res[msg->pr.pr_info.residx].registered = 0; /* * Unregister everybody else and build UA for * them */ for(i=0; i < 2*CTL_MAX_INITIATORS; i++) { if (lun->per_res[i].registered == 0) continue; if (!persis_offset && i < CTL_MAX_INITIATORS) lun->pending_sense[i].ua_pending |= CTL_UA_REG_PREEMPT; else if (persis_offset && i >= persis_offset) lun->pending_sense[i - persis_offset].ua_pending |= CTL_UA_REG_PREEMPT; lun->per_res[i].registered = 0; memset(&lun->per_res[i].res_key, 0, sizeof(struct scsi_per_res_key)); } lun->per_res[msg->pr.pr_info.residx].registered = 1; lun->pr_key_count = 1; lun->res_type = msg->pr.pr_info.res_type; if (lun->res_type != SPR_TYPE_WR_EX_AR && lun->res_type != SPR_TYPE_EX_AC_AR) lun->pr_res_idx = msg->pr.pr_info.residx; } else { for (i=0; i < 2*CTL_MAX_INITIATORS; i++) { if (memcmp(msg->pr.pr_info.sa_res_key, lun->per_res[i].res_key.key, sizeof(struct scsi_per_res_key)) != 0) continue; lun->per_res[i].registered = 0; memset(&lun->per_res[i].res_key, 0, sizeof(struct scsi_per_res_key)); lun->pr_key_count--; if (!persis_offset && i < persis_offset) lun->pending_sense[i].ua_pending |= CTL_UA_REG_PREEMPT; else if (persis_offset && i >= persis_offset) lun->pending_sense[i - persis_offset].ua_pending |= CTL_UA_REG_PREEMPT; } } } else { /* * Temporarily unregister so it won't get removed * or UA generated */ lun->per_res[msg->pr.pr_info.residx].registered = 0; for (i=0; i < 2*CTL_MAX_INITIATORS; i++) { if (lun->per_res[i].registered == 0) continue; if (memcmp(msg->pr.pr_info.sa_res_key, lun->per_res[i].res_key.key, sizeof(struct scsi_per_res_key)) == 0) { lun->per_res[i].registered = 0; memset(&lun->per_res[i].res_key, 0, sizeof(struct scsi_per_res_key)); lun->pr_key_count--; if (!persis_offset && i < CTL_MAX_INITIATORS) lun->pending_sense[i].ua_pending |= CTL_UA_REG_PREEMPT; else if (persis_offset && i >= persis_offset) lun->pending_sense[i - persis_offset].ua_pending |= CTL_UA_REG_PREEMPT; } else if (msg->pr.pr_info.res_type != lun->res_type && (lun->res_type == SPR_TYPE_WR_EX_RO || lun->res_type == SPR_TYPE_EX_AC_RO)) { if (!persis_offset && i < persis_offset) lun->pending_sense[i ].ua_pending |= CTL_UA_RES_RELEASE; else if (persis_offset && i >= persis_offset) lun->pending_sense[i - persis_offset].ua_pending |= CTL_UA_RES_RELEASE; } } lun->per_res[msg->pr.pr_info.residx].registered = 1; lun->res_type = msg->pr.pr_info.res_type; if (lun->res_type != SPR_TYPE_WR_EX_AR && lun->res_type != SPR_TYPE_EX_AC_AR) lun->pr_res_idx = msg->pr.pr_info.residx; else lun->pr_res_idx = CTL_PR_ALL_REGISTRANTS; } lun->PRGeneration++; } int ctl_persistent_reserve_out(struct ctl_scsiio *ctsio) { int retval; int isc_retval; u_int32_t param_len; struct scsi_per_res_out *cdb; struct ctl_lun *lun; struct scsi_per_res_out_parms* param; struct ctl_softc *softc; uint32_t residx; uint64_t res_key, sa_res_key; uint8_t type; union ctl_ha_msg persis_io; int i; CTL_DEBUG_PRINT(("ctl_persistent_reserve_out\n")); retval = CTL_RETVAL_COMPLETE; softc = control_softc; cdb = (struct scsi_per_res_out *)ctsio->cdb; lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; /* * We only support whole-LUN scope. The scope & type are ignored for * register, register and ignore existing key and clear. * We sometimes ignore scope and type on preempts too!! * Verify reservation type here as well. */ type = cdb->scope_type & SPR_TYPE_MASK; if ((cdb->action == SPRO_RESERVE) || (cdb->action == SPRO_RELEASE)) { if ((cdb->scope_type & SPR_SCOPE_MASK) != SPR_LU_SCOPE) { ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 1, /*bit*/ 4); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } if (type>8 || type==2 || type==4 || type==0) { ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 1, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } } switch (cdb->action & SPRO_ACTION_MASK) { case SPRO_REGISTER: case SPRO_RESERVE: case SPRO_RELEASE: case SPRO_CLEAR: case SPRO_PREEMPT: case SPRO_REG_IGNO: break; case SPRO_REG_MOVE: case SPRO_PRE_ABO: default: ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 1, /*bit_valid*/ 1, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); break; /* NOTREACHED */ } param_len = scsi_4btoul(cdb->length); if ((ctsio->io_hdr.flags & CTL_FLAG_ALLOCATED) == 0) { ctsio->kern_data_ptr = malloc(param_len, M_CTL, M_WAITOK); if (ctsio->kern_data_ptr == NULL) { ctl_set_busy(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } ctsio->kern_data_len = param_len; ctsio->kern_total_len = param_len; ctsio->kern_data_resid = 0; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; ctsio->io_hdr.flags |= CTL_FLAG_ALLOCATED; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } param = (struct scsi_per_res_out_parms *)ctsio->kern_data_ptr; residx = ctl_get_resindex(&ctsio->io_hdr.nexus); res_key = scsi_8btou64(param->res_key.key); sa_res_key = scsi_8btou64(param->serv_act_res_key); /* * Validate the reservation key here except for SPRO_REG_IGNO * This must be done for all other service actions */ if ((cdb->action & SPRO_ACTION_MASK) != SPRO_REG_IGNO) { mtx_lock(&softc->ctl_lock); if (lun->per_res[residx].registered) { if (memcmp(param->res_key.key, lun->per_res[residx].res_key.key, ctl_min(sizeof(param->res_key), sizeof(lun->per_res[residx].res_key))) != 0) { /* * The current key passed in doesn't match * the one the initiator previously * registered. */ mtx_unlock(&softc->ctl_lock); free(ctsio->kern_data_ptr, M_CTL); ctl_set_reservation_conflict(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } } else if ((cdb->action & SPRO_ACTION_MASK) != SPRO_REGISTER) { /* * We are not registered */ mtx_unlock(&softc->ctl_lock); free(ctsio->kern_data_ptr, M_CTL); ctl_set_reservation_conflict(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } else if (res_key != 0) { /* * We are not registered and trying to register but * the register key isn't zero. */ mtx_unlock(&softc->ctl_lock); free(ctsio->kern_data_ptr, M_CTL); ctl_set_reservation_conflict(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } mtx_unlock(&softc->ctl_lock); } switch (cdb->action & SPRO_ACTION_MASK) { case SPRO_REGISTER: case SPRO_REG_IGNO: { #if 0 printf("Registration received\n"); #endif /* * We don't support any of these options, as we report in * the read capabilities request (see * ctl_persistent_reserve_in(), above). */ if ((param->flags & SPR_SPEC_I_PT) || (param->flags & SPR_ALL_TG_PT) || (param->flags & SPR_APTPL)) { int bit_ptr; if (param->flags & SPR_APTPL) bit_ptr = 0; else if (param->flags & SPR_ALL_TG_PT) bit_ptr = 2; else /* SPR_SPEC_I_PT */ bit_ptr = 3; free(ctsio->kern_data_ptr, M_CTL); ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 0, /*field*/ 20, /*bit_valid*/ 1, /*bit*/ bit_ptr); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } mtx_lock(&softc->ctl_lock); /* * The initiator wants to clear the * key/unregister. */ if (sa_res_key == 0) { if ((res_key == 0 && (cdb->action & SPRO_ACTION_MASK) == SPRO_REGISTER) || ((cdb->action & SPRO_ACTION_MASK) == SPRO_REG_IGNO && !lun->per_res[residx].registered)) { mtx_unlock(&softc->ctl_lock); goto done; } lun->per_res[residx].registered = 0; memset(&lun->per_res[residx].res_key, 0, sizeof(lun->per_res[residx].res_key)); lun->pr_key_count--; if (residx == lun->pr_res_idx) { lun->flags &= ~CTL_LUN_PR_RESERVED; lun->pr_res_idx = CTL_PR_NO_RESERVATION; if ((lun->res_type == SPR_TYPE_WR_EX_RO || lun->res_type == SPR_TYPE_EX_AC_RO) && lun->pr_key_count) { /* * If the reservation is a registrants * only type we need to generate a UA * for other registered inits. The * sense code should be RESERVATIONS * RELEASED */ for (i = 0; i < CTL_MAX_INITIATORS;i++){ if (lun->per_res[ i+persis_offset].registered == 0) continue; lun->pending_sense[i ].ua_pending |= CTL_UA_RES_RELEASE; } } lun->res_type = 0; } else if (lun->pr_res_idx == CTL_PR_ALL_REGISTRANTS) { if (lun->pr_key_count==0) { lun->flags &= ~CTL_LUN_PR_RESERVED; lun->res_type = 0; lun->pr_res_idx = CTL_PR_NO_RESERVATION; } } persis_io.hdr.nexus = ctsio->io_hdr.nexus; persis_io.hdr.msg_type = CTL_MSG_PERS_ACTION; persis_io.pr.pr_info.action = CTL_PR_UNREG_KEY; persis_io.pr.pr_info.residx = residx; if ((isc_retval = ctl_ha_msg_send(CTL_HA_CHAN_CTL, &persis_io, sizeof(persis_io), 0 )) > CTL_HA_STATUS_SUCCESS) { printf("CTL:Persis Out error returned from " "ctl_ha_msg_send %d\n", isc_retval); } mtx_unlock(&softc->ctl_lock); } else /* sa_res_key != 0 */ { /* * If we aren't registered currently then increment * the key count and set the registered flag. */ if (!lun->per_res[residx].registered) { lun->pr_key_count++; lun->per_res[residx].registered = 1; } memcpy(&lun->per_res[residx].res_key, param->serv_act_res_key, ctl_min(sizeof(param->serv_act_res_key), sizeof(lun->per_res[residx].res_key))); persis_io.hdr.nexus = ctsio->io_hdr.nexus; persis_io.hdr.msg_type = CTL_MSG_PERS_ACTION; persis_io.pr.pr_info.action = CTL_PR_REG_KEY; persis_io.pr.pr_info.residx = residx; memcpy(persis_io.pr.pr_info.sa_res_key, param->serv_act_res_key, sizeof(param->serv_act_res_key)); mtx_unlock(&softc->ctl_lock); if ((isc_retval=ctl_ha_msg_send(CTL_HA_CHAN_CTL, &persis_io, sizeof(persis_io), 0)) > CTL_HA_STATUS_SUCCESS) { printf("CTL:Persis Out error returned from " "ctl_ha_msg_send %d\n", isc_retval); } } lun->PRGeneration++; break; } case SPRO_RESERVE: #if 0 printf("Reserve executed type %d\n", type); #endif mtx_lock(&softc->ctl_lock); if (lun->flags & CTL_LUN_PR_RESERVED) { /* * if this isn't the reservation holder and it's * not a "all registrants" type or if the type is * different then we have a conflict */ if ((lun->pr_res_idx != residx && lun->pr_res_idx != CTL_PR_ALL_REGISTRANTS) || lun->res_type != type) { mtx_unlock(&softc->ctl_lock); free(ctsio->kern_data_ptr, M_CTL); ctl_set_reservation_conflict(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } } else /* create a reservation */ { /* * If it's not an "all registrants" type record * reservation holder */ if (type != SPR_TYPE_WR_EX_AR && type != SPR_TYPE_EX_AC_AR) lun->pr_res_idx = residx; /* Res holder */ else lun->pr_res_idx = CTL_PR_ALL_REGISTRANTS; lun->flags |= CTL_LUN_PR_RESERVED; lun->res_type = type; mtx_unlock(&softc->ctl_lock); /* send msg to other side */ persis_io.hdr.nexus = ctsio->io_hdr.nexus; persis_io.hdr.msg_type = CTL_MSG_PERS_ACTION; persis_io.pr.pr_info.action = CTL_PR_RESERVE; persis_io.pr.pr_info.residx = lun->pr_res_idx; persis_io.pr.pr_info.res_type = type; if ((isc_retval=ctl_ha_msg_send(CTL_HA_CHAN_CTL, &persis_io, sizeof(persis_io), 0)) > CTL_HA_STATUS_SUCCESS) { printf("CTL:Persis Out error returned from " "ctl_ha_msg_send %d\n", isc_retval); } } break; case SPRO_RELEASE: mtx_lock(&softc->ctl_lock); if ((lun->flags & CTL_LUN_PR_RESERVED) == 0) { /* No reservation exists return good status */ mtx_unlock(&softc->ctl_lock); goto done; } /* * Is this nexus a reservation holder? */ if (lun->pr_res_idx != residx && lun->pr_res_idx != CTL_PR_ALL_REGISTRANTS) { /* * not a res holder return good status but * do nothing */ mtx_unlock(&softc->ctl_lock); goto done; } if (lun->res_type != type) { mtx_unlock(&softc->ctl_lock); free(ctsio->kern_data_ptr, M_CTL); ctl_set_illegal_pr_release(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* okay to release */ lun->flags &= ~CTL_LUN_PR_RESERVED; lun->pr_res_idx = CTL_PR_NO_RESERVATION; lun->res_type = 0; /* * if this isn't an exclusive access * res generate UA for all other * registrants. */ if (type != SPR_TYPE_EX_AC && type != SPR_TYPE_WR_EX) { /* * temporarily unregister so we don't generate UA */ lun->per_res[residx].registered = 0; for (i = 0; i < CTL_MAX_INITIATORS; i++) { if (lun->per_res[i+persis_offset].registered == 0) continue; lun->pending_sense[i].ua_pending |= CTL_UA_RES_RELEASE; } lun->per_res[residx].registered = 1; } mtx_unlock(&softc->ctl_lock); /* Send msg to other side */ persis_io.hdr.nexus = ctsio->io_hdr.nexus; persis_io.hdr.msg_type = CTL_MSG_PERS_ACTION; persis_io.pr.pr_info.action = CTL_PR_RELEASE; if ((isc_retval=ctl_ha_msg_send( CTL_HA_CHAN_CTL, &persis_io, sizeof(persis_io), 0)) > CTL_HA_STATUS_SUCCESS) { printf("CTL:Persis Out error returned from " "ctl_ha_msg_send %d\n", isc_retval); } break; case SPRO_CLEAR: /* send msg to other side */ mtx_lock(&softc->ctl_lock); lun->flags &= ~CTL_LUN_PR_RESERVED; lun->res_type = 0; lun->pr_key_count = 0; lun->pr_res_idx = CTL_PR_NO_RESERVATION; memset(&lun->per_res[residx].res_key, 0, sizeof(lun->per_res[residx].res_key)); lun->per_res[residx].registered = 0; for (i=0; i < 2*CTL_MAX_INITIATORS; i++) if (lun->per_res[i].registered) { if (!persis_offset && i < CTL_MAX_INITIATORS) lun->pending_sense[i].ua_pending |= CTL_UA_RES_PREEMPT; else if (persis_offset && i >= persis_offset) lun->pending_sense[i-persis_offset ].ua_pending |= CTL_UA_RES_PREEMPT; memset(&lun->per_res[i].res_key, 0, sizeof(struct scsi_per_res_key)); lun->per_res[i].registered = 0; } lun->PRGeneration++; mtx_unlock(&softc->ctl_lock); persis_io.hdr.nexus = ctsio->io_hdr.nexus; persis_io.hdr.msg_type = CTL_MSG_PERS_ACTION; persis_io.pr.pr_info.action = CTL_PR_CLEAR; if ((isc_retval=ctl_ha_msg_send(CTL_HA_CHAN_CTL, &persis_io, sizeof(persis_io), 0)) > CTL_HA_STATUS_SUCCESS) { printf("CTL:Persis Out error returned from " "ctl_ha_msg_send %d\n", isc_retval); } break; case SPRO_PREEMPT: { int nretval; nretval = ctl_pro_preempt(softc, lun, res_key, sa_res_key, type, residx, ctsio, cdb, param); if (nretval != 0) return (CTL_RETVAL_COMPLETE); break; } case SPRO_REG_MOVE: case SPRO_PRE_ABO: default: free(ctsio->kern_data_ptr, M_CTL); ctl_set_invalid_field(/*ctsio*/ ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 1, /*bit_valid*/ 1, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); break; /* NOTREACHED */ } done: free(ctsio->kern_data_ptr, M_CTL); ctl_set_success(ctsio); ctl_done((union ctl_io *)ctsio); return (retval); } /* * This routine is for handling a message from the other SC pertaining to * persistent reserve out. All the error checking will have been done * so only perorming the action need be done here to keep the two * in sync. */ static void ctl_hndl_per_res_out_on_other_sc(union ctl_ha_msg *msg) { struct ctl_lun *lun; struct ctl_softc *softc; int i; softc = control_softc; mtx_lock(&softc->ctl_lock); lun = softc->ctl_luns[msg->hdr.nexus.targ_lun]; switch(msg->pr.pr_info.action) { case CTL_PR_REG_KEY: if (!lun->per_res[msg->pr.pr_info.residx].registered) { lun->per_res[msg->pr.pr_info.residx].registered = 1; lun->pr_key_count++; } lun->PRGeneration++; memcpy(&lun->per_res[msg->pr.pr_info.residx].res_key, msg->pr.pr_info.sa_res_key, sizeof(struct scsi_per_res_key)); break; case CTL_PR_UNREG_KEY: lun->per_res[msg->pr.pr_info.residx].registered = 0; memset(&lun->per_res[msg->pr.pr_info.residx].res_key, 0, sizeof(struct scsi_per_res_key)); lun->pr_key_count--; /* XXX Need to see if the reservation has been released */ /* if so do we need to generate UA? */ if (msg->pr.pr_info.residx == lun->pr_res_idx) { lun->flags &= ~CTL_LUN_PR_RESERVED; lun->pr_res_idx = CTL_PR_NO_RESERVATION; if ((lun->res_type == SPR_TYPE_WR_EX_RO || lun->res_type == SPR_TYPE_EX_AC_RO) && lun->pr_key_count) { /* * If the reservation is a registrants * only type we need to generate a UA * for other registered inits. The * sense code should be RESERVATIONS * RELEASED */ for (i = 0; i < CTL_MAX_INITIATORS; i++) { if (lun->per_res[i+ persis_offset].registered == 0) continue; lun->pending_sense[i ].ua_pending |= CTL_UA_RES_RELEASE; } } lun->res_type = 0; } else if (lun->pr_res_idx == CTL_PR_ALL_REGISTRANTS) { if (lun->pr_key_count==0) { lun->flags &= ~CTL_LUN_PR_RESERVED; lun->res_type = 0; lun->pr_res_idx = CTL_PR_NO_RESERVATION; } } lun->PRGeneration++; break; case CTL_PR_RESERVE: lun->flags |= CTL_LUN_PR_RESERVED; lun->res_type = msg->pr.pr_info.res_type; lun->pr_res_idx = msg->pr.pr_info.residx; break; case CTL_PR_RELEASE: /* * if this isn't an exclusive access res generate UA for all * other registrants. */ if (lun->res_type != SPR_TYPE_EX_AC && lun->res_type != SPR_TYPE_WR_EX) { for (i = 0; i < CTL_MAX_INITIATORS; i++) if (lun->per_res[i+persis_offset].registered) lun->pending_sense[i].ua_pending |= CTL_UA_RES_RELEASE; } lun->flags &= ~CTL_LUN_PR_RESERVED; lun->pr_res_idx = CTL_PR_NO_RESERVATION; lun->res_type = 0; break; case CTL_PR_PREEMPT: ctl_pro_preempt_other(lun, msg); break; case CTL_PR_CLEAR: lun->flags &= ~CTL_LUN_PR_RESERVED; lun->res_type = 0; lun->pr_key_count = 0; lun->pr_res_idx = CTL_PR_NO_RESERVATION; for (i=0; i < 2*CTL_MAX_INITIATORS; i++) { if (lun->per_res[i].registered == 0) continue; if (!persis_offset && i < CTL_MAX_INITIATORS) lun->pending_sense[i].ua_pending |= CTL_UA_RES_PREEMPT; else if (persis_offset && i >= persis_offset) lun->pending_sense[i-persis_offset].ua_pending|= CTL_UA_RES_PREEMPT; memset(&lun->per_res[i].res_key, 0, sizeof(struct scsi_per_res_key)); lun->per_res[i].registered = 0; } lun->PRGeneration++; break; } mtx_unlock(&softc->ctl_lock); } int ctl_read_write(struct ctl_scsiio *ctsio) { struct ctl_lun *lun; struct ctl_lba_len lbalen; uint64_t lba; uint32_t num_blocks; int reladdr, fua, dpo, ebp; int retval; int isread; lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; CTL_DEBUG_PRINT(("ctl_read_write: command: %#x\n", ctsio->cdb[0])); reladdr = 0; fua = 0; dpo = 0; ebp = 0; retval = CTL_RETVAL_COMPLETE; isread = ctsio->cdb[0] == READ_6 || ctsio->cdb[0] == READ_10 || ctsio->cdb[0] == READ_12 || ctsio->cdb[0] == READ_16; if (lun->flags & CTL_LUN_PR_RESERVED && isread) { uint32_t residx; /* * XXX KDM need a lock here. */ residx = ctl_get_resindex(&ctsio->io_hdr.nexus); if ((lun->res_type == SPR_TYPE_EX_AC && residx != lun->pr_res_idx) || ((lun->res_type == SPR_TYPE_EX_AC_RO || lun->res_type == SPR_TYPE_EX_AC_AR) && !lun->per_res[residx].registered)) { ctl_set_reservation_conflict(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } } switch (ctsio->cdb[0]) { case READ_6: case WRITE_6: { struct scsi_rw_6 *cdb; cdb = (struct scsi_rw_6 *)ctsio->cdb; lba = scsi_3btoul(cdb->addr); /* only 5 bits are valid in the most significant address byte */ lba &= 0x1fffff; num_blocks = cdb->length; /* * This is correct according to SBC-2. */ if (num_blocks == 0) num_blocks = 256; break; } case READ_10: case WRITE_10: { struct scsi_rw_10 *cdb; cdb = (struct scsi_rw_10 *)ctsio->cdb; if (cdb->byte2 & SRW10_RELADDR) reladdr = 1; if (cdb->byte2 & SRW10_FUA) fua = 1; if (cdb->byte2 & SRW10_DPO) dpo = 1; if ((cdb->opcode == WRITE_10) && (cdb->byte2 & SRW10_EBP)) ebp = 1; lba = scsi_4btoul(cdb->addr); num_blocks = scsi_2btoul(cdb->length); break; } case WRITE_VERIFY_10: { struct scsi_write_verify_10 *cdb; cdb = (struct scsi_write_verify_10 *)ctsio->cdb; /* * XXX KDM we should do actual write verify support at some * point. This is obviously fake, we're just translating * things to a write. So we don't even bother checking the * BYTCHK field, since we don't do any verification. If * the user asks for it, we'll just pretend we did it. */ if (cdb->byte2 & SWV_DPO) dpo = 1; lba = scsi_4btoul(cdb->addr); num_blocks = scsi_2btoul(cdb->length); break; } case READ_12: case WRITE_12: { struct scsi_rw_12 *cdb; cdb = (struct scsi_rw_12 *)ctsio->cdb; if (cdb->byte2 & SRW12_RELADDR) reladdr = 1; if (cdb->byte2 & SRW12_FUA) fua = 1; if (cdb->byte2 & SRW12_DPO) dpo = 1; lba = scsi_4btoul(cdb->addr); num_blocks = scsi_4btoul(cdb->length); break; } case WRITE_VERIFY_12: { struct scsi_write_verify_12 *cdb; cdb = (struct scsi_write_verify_12 *)ctsio->cdb; if (cdb->byte2 & SWV_DPO) dpo = 1; lba = scsi_4btoul(cdb->addr); num_blocks = scsi_4btoul(cdb->length); break; } case READ_16: case WRITE_16: { struct scsi_rw_16 *cdb; cdb = (struct scsi_rw_16 *)ctsio->cdb; if (cdb->byte2 & SRW12_RELADDR) reladdr = 1; if (cdb->byte2 & SRW12_FUA) fua = 1; if (cdb->byte2 & SRW12_DPO) dpo = 1; lba = scsi_8btou64(cdb->addr); num_blocks = scsi_4btoul(cdb->length); break; } case WRITE_VERIFY_16: { struct scsi_write_verify_16 *cdb; cdb = (struct scsi_write_verify_16 *)ctsio->cdb; if (cdb->byte2 & SWV_DPO) dpo = 1; lba = scsi_8btou64(cdb->addr); num_blocks = scsi_4btoul(cdb->length); break; } default: /* * We got a command we don't support. This shouldn't * happen, commands should be filtered out above us. */ ctl_set_invalid_opcode(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); break; /* NOTREACHED */ } /* * XXX KDM what do we do with the DPO and FUA bits? FUA might be * interesting for us, but if RAIDCore is in write-back mode, * getting it to do write-through for a particular transaction may * not be possible. */ /* * We don't support relative addressing. That also requires * supporting linked commands, which we don't do. */ if (reladdr != 0) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 1, /*bit_valid*/ 1, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * The first check is to make sure we're in bounds, the second * check is to catch wrap-around problems. If the lba + num blocks * is less than the lba, then we've wrapped around and the block * range is invalid anyway. */ if (((lba + num_blocks) > (lun->be_lun->maxlba + 1)) || ((lba + num_blocks) < lba)) { ctl_set_lba_out_of_range(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } /* * According to SBC-3, a transfer length of 0 is not an error. * Note that this cannot happen with WRITE(6) or READ(6), since 0 * translates to 256 blocks for those commands. */ if (num_blocks == 0) { ctl_set_success(ctsio); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } lbalen.lba = lba; lbalen.len = num_blocks; memcpy(ctsio->io_hdr.ctl_private[CTL_PRIV_LBA_LEN].bytes, &lbalen, sizeof(lbalen)); CTL_DEBUG_PRINT(("ctl_read_write: calling data_submit()\n")); retval = lun->backend->data_submit((union ctl_io *)ctsio); return (retval); } int ctl_report_luns(struct ctl_scsiio *ctsio) { struct scsi_report_luns *cdb; struct scsi_report_luns_data *lun_data; struct ctl_lun *lun, *request_lun; int num_luns, retval; uint32_t alloc_len, lun_datalen; int num_filled, well_known; uint32_t initidx; retval = CTL_RETVAL_COMPLETE; well_known = 0; cdb = (struct scsi_report_luns *)ctsio->cdb; CTL_DEBUG_PRINT(("ctl_report_luns\n")); mtx_lock(&control_softc->ctl_lock); num_luns = control_softc->num_luns; mtx_unlock(&control_softc->ctl_lock); switch (cdb->select_report) { case RPL_REPORT_DEFAULT: case RPL_REPORT_ALL: break; case RPL_REPORT_WELLKNOWN: well_known = 1; num_luns = 0; break; default: ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (retval); break; /* NOTREACHED */ } alloc_len = scsi_4btoul(cdb->length); /* * The initiator has to allocate at least 16 bytes for this request, * so he can at least get the header and the first LUN. Otherwise * we reject the request (per SPC-3 rev 14, section 6.21). */ if (alloc_len < (sizeof(struct scsi_report_luns_data) + sizeof(struct scsi_report_luns_lundata))) { ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 6, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); return (retval); } request_lun = (struct ctl_lun *) ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; lun_datalen = sizeof(*lun_data) + (num_luns * sizeof(struct scsi_report_luns_lundata)); ctsio->kern_data_ptr = malloc(lun_datalen, M_CTL, M_WAITOK); if (ctsio->kern_data_ptr == NULL) { ctsio->io_hdr.status = CTL_SCSI_ERROR; ctsio->scsi_status = SCSI_STATUS_BUSY; ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } lun_data = (struct scsi_report_luns_data *)ctsio->kern_data_ptr; ctsio->kern_sg_entries = 0; if (lun_datalen < alloc_len) { ctsio->residual = alloc_len - lun_datalen; ctsio->kern_data_len = lun_datalen; ctsio->kern_total_len = lun_datalen; } else { ctsio->residual = 0; ctsio->kern_data_len = alloc_len; ctsio->kern_total_len = alloc_len; } ctsio->kern_data_resid = 0; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; initidx = ctl_get_initindex(&ctsio->io_hdr.nexus); memset(lun_data, 0, lun_datalen); /* * We set this to the actual data length, regardless of how much * space we actually have to return results. If the user looks at * this value, he'll know whether or not he allocated enough space * and reissue the command if necessary. We don't support well * known logical units, so if the user asks for that, return none. */ scsi_ulto4b(lun_datalen - 8, lun_data->length); mtx_lock(&control_softc->ctl_lock); for (num_filled = 0, lun = STAILQ_FIRST(&control_softc->lun_list); (lun != NULL) && (num_filled < num_luns); lun = STAILQ_NEXT(lun, links)) { if (lun->lun <= 0xff) { /* * Peripheral addressing method, bus number 0. */ lun_data->luns[num_filled].lundata[0] = RPL_LUNDATA_ATYP_PERIPH; lun_data->luns[num_filled].lundata[1] = lun->lun; num_filled++; } else if (lun->lun <= 0x3fff) { /* * Flat addressing method. */ lun_data->luns[num_filled].lundata[0] = RPL_LUNDATA_ATYP_FLAT | (lun->lun & RPL_LUNDATA_FLAT_LUN_MASK); #ifdef OLDCTLHEADERS (SRLD_ADDR_FLAT << SRLD_ADDR_SHIFT) | (lun->lun & SRLD_BUS_LUN_MASK); #endif lun_data->luns[num_filled].lundata[1] = #ifdef OLDCTLHEADERS lun->lun >> SRLD_BUS_LUN_BITS; #endif lun->lun >> RPL_LUNDATA_FLAT_LUN_BITS; num_filled++; } else { printf("ctl_report_luns: bogus LUN number %jd, " "skipping\n", (intmax_t)lun->lun); } /* * According to SPC-3, rev 14 section 6.21: * * "The execution of a REPORT LUNS command to any valid and * installed logical unit shall clear the REPORTED LUNS DATA * HAS CHANGED unit attention condition for all logical * units of that target with respect to the requesting * initiator. A valid and installed logical unit is one * having a PERIPHERAL QUALIFIER of 000b in the standard * INQUIRY data (see 6.4.2)." * * If request_lun is NULL, the LUN this report luns command * was issued to is either disabled or doesn't exist. In that * case, we shouldn't clear any pending lun change unit * attention. */ if (request_lun != NULL) lun->pending_sense[initidx].ua_pending &= ~CTL_UA_LUN_CHANGE; } mtx_unlock(&control_softc->ctl_lock); /* * We can only return SCSI_STATUS_CHECK_COND when we can't satisfy * this request. */ ctsio->scsi_status = SCSI_STATUS_OK; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (retval); } int ctl_request_sense(struct ctl_scsiio *ctsio) { struct scsi_request_sense *cdb; struct scsi_sense_data *sense_ptr; struct ctl_lun *lun; uint32_t initidx; int have_error; scsi_sense_data_type sense_format; cdb = (struct scsi_request_sense *)ctsio->cdb; lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; CTL_DEBUG_PRINT(("ctl_request_sense\n")); /* * Determine which sense format the user wants. */ if (cdb->byte2 & SRS_DESC) sense_format = SSD_TYPE_DESC; else sense_format = SSD_TYPE_FIXED; ctsio->kern_data_ptr = malloc(sizeof(*sense_ptr), M_CTL, M_WAITOK); if (ctsio->kern_data_ptr == NULL) { ctsio->io_hdr.status = CTL_SCSI_ERROR; ctsio->scsi_status = SCSI_STATUS_BUSY; ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } sense_ptr = (struct scsi_sense_data *)ctsio->kern_data_ptr; ctsio->kern_sg_entries = 0; /* * struct scsi_sense_data, which is currently set to 256 bytes, is * larger than the largest allowed value for the length field in the * REQUEST SENSE CDB, which is 252 bytes as of SPC-4. */ ctsio->residual = 0; ctsio->kern_data_len = cdb->length; ctsio->kern_total_len = cdb->length; ctsio->kern_data_resid = 0; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; /* * If we don't have a LUN, we don't have any pending sense. */ if (lun == NULL) goto no_sense; have_error = 0; initidx = ctl_get_initindex(&ctsio->io_hdr.nexus); /* * Check for pending sense, and then for pending unit attentions. * Pending sense gets returned first, then pending unit attentions. */ mtx_lock(&lun->ctl_softc->ctl_lock); if (ctl_is_set(lun->have_ca, initidx)) { scsi_sense_data_type stored_format; /* * Check to see which sense format was used for the stored * sense data. */ stored_format = scsi_sense_type( &lun->pending_sense[initidx].sense); /* * If the user requested a different sense format than the * one we stored, then we need to convert it to the other * format. If we're going from descriptor to fixed format * sense data, we may lose things in translation, depending * on what options were used. * * If the stored format is SSD_TYPE_NONE (i.e. invalid), * for some reason we'll just copy it out as-is. */ if ((stored_format == SSD_TYPE_FIXED) && (sense_format == SSD_TYPE_DESC)) ctl_sense_to_desc((struct scsi_sense_data_fixed *) &lun->pending_sense[initidx].sense, (struct scsi_sense_data_desc *)sense_ptr); else if ((stored_format == SSD_TYPE_DESC) && (sense_format == SSD_TYPE_FIXED)) ctl_sense_to_fixed((struct scsi_sense_data_desc *) &lun->pending_sense[initidx].sense, (struct scsi_sense_data_fixed *)sense_ptr); else memcpy(sense_ptr, &lun->pending_sense[initidx].sense, ctl_min(sizeof(*sense_ptr), sizeof(lun->pending_sense[initidx].sense))); ctl_clear_mask(lun->have_ca, initidx); have_error = 1; } else if (lun->pending_sense[initidx].ua_pending != CTL_UA_NONE) { ctl_ua_type ua_type; ua_type = ctl_build_ua(lun->pending_sense[initidx].ua_pending, sense_ptr, sense_format); if (ua_type != CTL_UA_NONE) { have_error = 1; /* We're reporting this UA, so clear it */ lun->pending_sense[initidx].ua_pending &= ~ua_type; } } mtx_unlock(&lun->ctl_softc->ctl_lock); /* * We already have a pending error, return it. */ if (have_error != 0) { /* * We report the SCSI status as OK, since the status of the * request sense command itself is OK. */ ctsio->scsi_status = SCSI_STATUS_OK; /* * We report 0 for the sense length, because we aren't doing * autosense in this case. We're reporting sense as * parameter data. */ ctsio->sense_len = 0; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } no_sense: /* * No sense information to report, so we report that everything is * okay. */ ctl_set_sense_data(sense_ptr, lun, sense_format, /*current_error*/ 1, /*sense_key*/ SSD_KEY_NO_SENSE, /*asc*/ 0x00, /*ascq*/ 0x00, SSD_ELEM_NONE); ctsio->scsi_status = SCSI_STATUS_OK; /* * We report 0 for the sense length, because we aren't doing * autosense in this case. We're reporting sense as parameter data. */ ctsio->sense_len = 0; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } int ctl_tur(struct ctl_scsiio *ctsio) { struct ctl_lun *lun; lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; CTL_DEBUG_PRINT(("ctl_tur\n")); if (lun == NULL) return (-EINVAL); ctsio->scsi_status = SCSI_STATUS_OK; ctsio->io_hdr.status = CTL_SUCCESS; ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } #ifdef notyet static int ctl_cmddt_inquiry(struct ctl_scsiio *ctsio) { } #endif static int ctl_inquiry_evpd_supported(struct ctl_scsiio *ctsio, int alloc_len) { struct scsi_vpd_supported_pages *pages; int sup_page_size; struct ctl_lun *lun; lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; sup_page_size = sizeof(struct scsi_vpd_supported_pages) + SCSI_EVPD_NUM_SUPPORTED_PAGES; /* * XXX KDM GFP_??? We probably don't want to wait here, * unless we end up having a process/thread context. */ ctsio->kern_data_ptr = malloc(sup_page_size, M_CTL, M_WAITOK); if (ctsio->kern_data_ptr == NULL) { ctsio->io_hdr.status = CTL_SCSI_ERROR; ctsio->scsi_status = SCSI_STATUS_BUSY; ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } pages = (struct scsi_vpd_supported_pages *)ctsio->kern_data_ptr; ctsio->kern_sg_entries = 0; if (sup_page_size < alloc_len) { ctsio->residual = alloc_len - sup_page_size; ctsio->kern_data_len = sup_page_size; ctsio->kern_total_len = sup_page_size; } else { ctsio->residual = 0; ctsio->kern_data_len = alloc_len; ctsio->kern_total_len = alloc_len; } ctsio->kern_data_resid = 0; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; memset(pages, 0, sup_page_size); /* * The control device is always connected. The disk device, on the * other hand, may not be online all the time. Need to change this * to figure out whether the disk device is actually online or not. */ if (lun != NULL) pages->device = (SID_QUAL_LU_CONNECTED << 5) | lun->be_lun->lun_type; else pages->device = (SID_QUAL_LU_OFFLINE << 5) | T_DIRECT; pages->length = SCSI_EVPD_NUM_SUPPORTED_PAGES; /* Supported VPD pages */ pages->page_list[0] = SVPD_SUPPORTED_PAGES; /* Serial Number */ pages->page_list[1] = SVPD_UNIT_SERIAL_NUMBER; /* Device Identification */ pages->page_list[2] = SVPD_DEVICE_ID; ctsio->scsi_status = SCSI_STATUS_OK; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } static int ctl_inquiry_evpd_serial(struct ctl_scsiio *ctsio, int alloc_len) { struct scsi_vpd_unit_serial_number *sn_ptr; struct ctl_lun *lun; #ifndef CTL_USE_BACKEND_SN char tmpstr[32]; #endif lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; /* XXX KDM which malloc flags here?? */ ctsio->kern_data_ptr = malloc(sizeof(*sn_ptr), M_CTL, M_WAITOK); if (ctsio->kern_data_ptr == NULL) { ctsio->io_hdr.status = CTL_SCSI_ERROR; ctsio->scsi_status = SCSI_STATUS_BUSY; ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } sn_ptr = (struct scsi_vpd_unit_serial_number *)ctsio->kern_data_ptr; ctsio->kern_sg_entries = 0; if (sizeof(*sn_ptr) < alloc_len) { ctsio->residual = alloc_len - sizeof(*sn_ptr); ctsio->kern_data_len = sizeof(*sn_ptr); ctsio->kern_total_len = sizeof(*sn_ptr); } else { ctsio->residual = 0; ctsio->kern_data_len = alloc_len; ctsio->kern_total_len = alloc_len; } ctsio->kern_data_resid = 0; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; memset(sn_ptr, 0, sizeof(*sn_ptr)); /* * The control device is always connected. The disk device, on the * other hand, may not be online all the time. Need to change this * to figure out whether the disk device is actually online or not. */ if (lun != NULL) sn_ptr->device = (SID_QUAL_LU_CONNECTED << 5) | lun->be_lun->lun_type; else sn_ptr->device = (SID_QUAL_LU_OFFLINE << 5) | T_DIRECT; sn_ptr->page_code = SVPD_UNIT_SERIAL_NUMBER; sn_ptr->length = ctl_min(sizeof(*sn_ptr) - 4, CTL_SN_LEN); #ifdef CTL_USE_BACKEND_SN /* * If we don't have a LUN, we just leave the serial number as * all spaces. */ memset(sn_ptr->serial_num, 0x20, sizeof(sn_ptr->serial_num)); if (lun != NULL) { strncpy((char *)sn_ptr->serial_num, (char *)lun->be_lun->serial_num, CTL_SN_LEN); } #else /* * Note that we're using a non-unique serial number here, */ snprintf(tmpstr, sizeof(tmpstr), "MYSERIALNUMIS000"); memset(sn_ptr->serial_num, 0x20, sizeof(sn_ptr->serial_num)); strncpy(sn_ptr->serial_num, tmpstr, ctl_min(CTL_SN_LEN, ctl_min(sizeof(tmpstr), sizeof(*sn_ptr) - 4))); #endif ctsio->scsi_status = SCSI_STATUS_OK; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } static int ctl_inquiry_evpd_devid(struct ctl_scsiio *ctsio, int alloc_len) { struct scsi_vpd_device_id *devid_ptr; struct scsi_vpd_id_descriptor *desc, *desc1; struct scsi_vpd_id_descriptor *desc2, *desc3; /* for types 4h and 5h */ struct scsi_vpd_id_t10 *t10id; struct ctl_softc *ctl_softc; struct ctl_lun *lun; struct ctl_frontend *fe; #ifndef CTL_USE_BACKEND_SN char tmpstr[32]; #endif /* CTL_USE_BACKEND_SN */ int devid_len; ctl_softc = control_softc; lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; devid_len = sizeof(struct scsi_vpd_device_id) + sizeof(struct scsi_vpd_id_descriptor) + sizeof(struct scsi_vpd_id_t10) + CTL_DEVID_LEN + sizeof(struct scsi_vpd_id_descriptor) + CTL_WWPN_LEN + sizeof(struct scsi_vpd_id_descriptor) + sizeof(struct scsi_vpd_id_rel_trgt_port_id) + sizeof(struct scsi_vpd_id_descriptor) + sizeof(struct scsi_vpd_id_trgt_port_grp_id); /* XXX KDM which malloc flags here ?? */ ctsio->kern_data_ptr = malloc(devid_len, M_CTL, M_WAITOK); if (ctsio->kern_data_ptr == NULL) { ctsio->io_hdr.status = CTL_SCSI_ERROR; ctsio->scsi_status = SCSI_STATUS_BUSY; ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } devid_ptr = (struct scsi_vpd_device_id *)ctsio->kern_data_ptr; ctsio->kern_sg_entries = 0; if (devid_len < alloc_len) { ctsio->residual = alloc_len - devid_len; ctsio->kern_data_len = devid_len; ctsio->kern_total_len = devid_len; } else { ctsio->residual = 0; ctsio->kern_data_len = alloc_len; ctsio->kern_total_len = alloc_len; } ctsio->kern_data_resid = 0; ctsio->kern_rel_offset = 0; ctsio->kern_sg_entries = 0; desc = (struct scsi_vpd_id_descriptor *)devid_ptr->desc_list; t10id = (struct scsi_vpd_id_t10 *)&desc->identifier[0]; desc1 = (struct scsi_vpd_id_descriptor *)(&desc->identifier[0] + sizeof(struct scsi_vpd_id_t10) + CTL_DEVID_LEN); desc2 = (struct scsi_vpd_id_descriptor *)(&desc1->identifier[0] + CTL_WWPN_LEN); desc3 = (struct scsi_vpd_id_descriptor *)(&desc2->identifier[0] + sizeof(struct scsi_vpd_id_rel_trgt_port_id)); memset(devid_ptr, 0, devid_len); /* * The control device is always connected. The disk device, on the * other hand, may not be online all the time. */ if (lun != NULL) devid_ptr->device = (SID_QUAL_LU_CONNECTED << 5) | lun->be_lun->lun_type; else devid_ptr->device = (SID_QUAL_LU_OFFLINE << 5) | T_DIRECT; devid_ptr->page_code = SVPD_DEVICE_ID; scsi_ulto2b(devid_len - 4, devid_ptr->length); mtx_lock(&ctl_softc->ctl_lock); fe = ctl_softc->ctl_ports[ctl_port_idx(ctsio->io_hdr.nexus.targ_port)]; /* * For Fibre channel, */ if (fe->port_type == CTL_PORT_FC) { desc->proto_codeset = (SCSI_PROTO_FC << 4) | SVPD_ID_CODESET_ASCII; desc1->proto_codeset = (SCSI_PROTO_FC << 4) | SVPD_ID_CODESET_BINARY; } else { desc->proto_codeset = (SCSI_PROTO_SPI << 4) | SVPD_ID_CODESET_ASCII; desc1->proto_codeset = (SCSI_PROTO_SPI << 4) | SVPD_ID_CODESET_BINARY; } desc2->proto_codeset = desc3->proto_codeset = desc1->proto_codeset; mtx_unlock(&ctl_softc->ctl_lock); /* * We're using a LUN association here. i.e., this device ID is a * per-LUN identifier. */ desc->id_type = SVPD_ID_PIV | SVPD_ID_ASSOC_LUN | SVPD_ID_TYPE_T10; desc->length = sizeof(*t10id) + CTL_DEVID_LEN; strncpy((char *)t10id->vendor, CTL_VENDOR, sizeof(t10id->vendor)); /* * desc1 is for the WWPN which is a port asscociation. */ desc1->id_type = SVPD_ID_PIV | SVPD_ID_ASSOC_PORT | SVPD_ID_TYPE_NAA; desc1->length = CTL_WWPN_LEN; /* XXX Call Reggie's get_WWNN func here then add port # to the end */ /* For testing just create the WWPN */ #if 0 ddb_GetWWNN((char *)desc1->identifier); /* NOTE: if the port is 0 or 8 we don't want to subtract 1 */ /* This is so Copancontrol will return something sane */ if (ctsio->io_hdr.nexus.targ_port!=0 && ctsio->io_hdr.nexus.targ_port!=8) desc1->identifier[7] += ctsio->io_hdr.nexus.targ_port-1; else desc1->identifier[7] += ctsio->io_hdr.nexus.targ_port; #endif be64enc(desc1->identifier, fe->wwpn); /* * desc2 is for the Relative Target Port(type 4h) identifier */ desc2->id_type = SVPD_ID_PIV | SVPD_ID_ASSOC_PORT | SVPD_ID_TYPE_RELTARG; desc2->length = 4; //#if 0 /* NOTE: if the port is 0 or 8 we don't want to subtract 1 */ /* This is so Copancontrol will return something sane */ if (ctsio->io_hdr.nexus.targ_port!=0 && ctsio->io_hdr.nexus.targ_port!=8) desc2->identifier[3] = ctsio->io_hdr.nexus.targ_port - 1; else desc2->identifier[3] = ctsio->io_hdr.nexus.targ_port; //#endif /* * desc3 is for the Target Port Group(type 5h) identifier */ desc3->id_type = SVPD_ID_PIV | SVPD_ID_ASSOC_PORT | SVPD_ID_TYPE_TPORTGRP; desc3->length = 4; if (ctsio->io_hdr.nexus.targ_port < CTL_MAX_PORTS || ctl_is_single) desc3->identifier[3] = 1; else desc3->identifier[3] = 2; #ifdef CTL_USE_BACKEND_SN /* * If we've actually got a backend, copy the device id from the * per-LUN data. Otherwise, set it to all spaces. */ if (lun != NULL) { /* * Copy the backend's LUN ID. */ strncpy((char *)t10id->vendor_spec_id, (char *)lun->be_lun->device_id, CTL_DEVID_LEN); } else { /* * No backend, set this to spaces. */ memset(t10id->vendor_spec_id, 0x20, CTL_DEVID_LEN); } #else snprintf(tmpstr, sizeof(tmpstr), "MYDEVICEIDIS%4d", (lun != NULL) ? (int)lun->lun : 0); strncpy(t10id->vendor_spec_id, tmpstr, ctl_min(CTL_DEVID_LEN, sizeof(tmpstr))); #endif ctsio->scsi_status = SCSI_STATUS_OK; ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } static int ctl_inquiry_evpd(struct ctl_scsiio *ctsio) { struct scsi_inquiry *cdb; int alloc_len, retval; cdb = (struct scsi_inquiry *)ctsio->cdb; retval = CTL_RETVAL_COMPLETE; alloc_len = scsi_2btoul(cdb->length); switch (cdb->page_code) { case SVPD_SUPPORTED_PAGES: retval = ctl_inquiry_evpd_supported(ctsio, alloc_len); break; case SVPD_UNIT_SERIAL_NUMBER: retval = ctl_inquiry_evpd_serial(ctsio, alloc_len); break; case SVPD_DEVICE_ID: retval = ctl_inquiry_evpd_devid(ctsio, alloc_len); break; default: ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 2, /*bit_valid*/ 0, /*bit*/ 0); ctl_done((union ctl_io *)ctsio); retval = CTL_RETVAL_COMPLETE; break; } return (retval); } static int ctl_inquiry_std(struct ctl_scsiio *ctsio) { struct scsi_inquiry_data *inq_ptr; struct scsi_inquiry *cdb; struct ctl_softc *ctl_softc; struct ctl_lun *lun; uint32_t alloc_len; int is_fc; ctl_softc = control_softc; /* * Figure out whether we're talking to a Fibre Channel port or not. * We treat the ioctl front end, and any SCSI adapters, as packetized * SCSI front ends. */ mtx_lock(&ctl_softc->ctl_lock); if (ctl_softc->ctl_ports[ctl_port_idx(ctsio->io_hdr.nexus.targ_port)]->port_type != CTL_PORT_FC) is_fc = 0; else is_fc = 1; mtx_unlock(&ctl_softc->ctl_lock); lun = ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; cdb = (struct scsi_inquiry *)ctsio->cdb; alloc_len = scsi_2btoul(cdb->length); /* * We malloc the full inquiry data size here and fill it * in. If the user only asks for less, we'll give him * that much. */ /* XXX KDM what malloc flags should we use here?? */ ctsio->kern_data_ptr = malloc(sizeof(*inq_ptr), M_CTL, M_WAITOK); if (ctsio->kern_data_ptr == NULL) { ctsio->io_hdr.status = CTL_SCSI_ERROR; ctsio->scsi_status = SCSI_STATUS_BUSY; ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } inq_ptr = (struct scsi_inquiry_data *)ctsio->kern_data_ptr; ctsio->kern_sg_entries = 0; ctsio->kern_data_resid = 0; ctsio->kern_rel_offset = 0; if (sizeof(*inq_ptr) < alloc_len) { ctsio->residual = alloc_len - sizeof(*inq_ptr); ctsio->kern_data_len = sizeof(*inq_ptr); ctsio->kern_total_len = sizeof(*inq_ptr); } else { ctsio->residual = 0; ctsio->kern_data_len = alloc_len; ctsio->kern_total_len = alloc_len; } memset(inq_ptr, 0, sizeof(*inq_ptr)); /* * If we have a LUN configured, report it as connected. Otherwise, * report that it is offline or no device is supported, depending * on the value of inquiry_pq_no_lun. * * According to the spec (SPC-4 r34), the peripheral qualifier * SID_QUAL_LU_OFFLINE (001b) is used in the following scenario: * * "A peripheral device having the specified peripheral device type * is not connected to this logical unit. However, the device * server is capable of supporting the specified peripheral device * type on this logical unit." * * According to the same spec, the peripheral qualifier * SID_QUAL_BAD_LU (011b) is used in this scenario: * * "The device server is not capable of supporting a peripheral * device on this logical unit. For this peripheral qualifier the * peripheral device type shall be set to 1Fh. All other peripheral * device type values are reserved for this peripheral qualifier." * * Given the text, it would seem that we probably want to report that * the LUN is offline here. There is no LUN connected, but we can * support a LUN at the given LUN number. * * In the real world, though, it sounds like things are a little * different: * * - Linux, when presented with a LUN with the offline peripheral * qualifier, will create an sg driver instance for it. So when * you attach it to CTL, you wind up with a ton of sg driver * instances. (One for every LUN that Linux bothered to probe.) * Linux does this despite the fact that it issues a REPORT LUNs * to LUN 0 to get the inventory of supported LUNs. * * - There is other anecdotal evidence (from Emulex folks) about * arrays that use the offline peripheral qualifier for LUNs that * are on the "passive" path in an active/passive array. * * So the solution is provide a hopefully reasonable default * (return bad/no LUN) and allow the user to change the behavior * with a tunable/sysctl variable. */ if (lun != NULL) inq_ptr->device = (SID_QUAL_LU_CONNECTED << 5) | lun->be_lun->lun_type; else if (ctl_softc->inquiry_pq_no_lun == 0) inq_ptr->device = (SID_QUAL_LU_OFFLINE << 5) | T_DIRECT; else inq_ptr->device = (SID_QUAL_BAD_LU << 5) | T_NODEVICE; /* RMB in byte 2 is 0 */ inq_ptr->version = SCSI_REV_SPC3; /* * According to SAM-3, even if a device only supports a single * level of LUN addressing, it should still set the HISUP bit: * * 4.9.1 Logical unit numbers overview * * All logical unit number formats described in this standard are * hierarchical in structure even when only a single level in that * hierarchy is used. The HISUP bit shall be set to one in the * standard INQUIRY data (see SPC-2) when any logical unit number * format described in this standard is used. Non-hierarchical * formats are outside the scope of this standard. * * Therefore we set the HiSup bit here. * * The reponse format is 2, per SPC-3. */ inq_ptr->response_format = SID_HiSup | 2; inq_ptr->additional_length = sizeof(*inq_ptr) - 4; CTL_DEBUG_PRINT(("additional_length = %d\n", inq_ptr->additional_length)); inq_ptr->spc3_flags = SPC3_SID_TPGS_IMPLICIT; /* 16 bit addressing */ if (is_fc == 0) inq_ptr->spc2_flags = SPC2_SID_ADDR16; /* XXX set the SID_MultiP bit here if we're actually going to respond on multiple ports */ inq_ptr->spc2_flags |= SPC2_SID_MultiP; /* 16 bit data bus, synchronous transfers */ /* XXX these flags don't apply for FC */ if (is_fc == 0) inq_ptr->flags = SID_WBus16 | SID_Sync; /* * XXX KDM do we want to support tagged queueing on the control * device at all? */ if ((lun == NULL) || (lun->be_lun->lun_type != T_PROCESSOR)) inq_ptr->flags |= SID_CmdQue; /* * Per SPC-3, unused bytes in ASCII strings are filled with spaces. * We have 8 bytes for the vendor name, and 16 bytes for the device * name and 4 bytes for the revision. */ strncpy(inq_ptr->vendor, CTL_VENDOR, sizeof(inq_ptr->vendor)); if (lun == NULL) { strcpy(inq_ptr->product, CTL_DIRECT_PRODUCT); } else { switch (lun->be_lun->lun_type) { case T_DIRECT: strcpy(inq_ptr->product, CTL_DIRECT_PRODUCT); break; case T_PROCESSOR: strcpy(inq_ptr->product, CTL_PROCESSOR_PRODUCT); break; default: strcpy(inq_ptr->product, CTL_UNKNOWN_PRODUCT); break; } } /* * XXX make this a macro somewhere so it automatically gets * incremented when we make changes. */ strncpy(inq_ptr->revision, "0001", sizeof(inq_ptr->revision)); /* * For parallel SCSI, we support double transition and single * transition clocking. We also support QAS (Quick Arbitration * and Selection) and Information Unit transfers on both the * control and array devices. */ if (is_fc == 0) inq_ptr->spi3data = SID_SPI_CLOCK_DT_ST | SID_SPI_QAS | SID_SPI_IUS; /* SAM-3 */ scsi_ulto2b(0x0060, inq_ptr->version1); /* SPC-3 (no version claimed) XXX should we claim a version? */ scsi_ulto2b(0x0300, inq_ptr->version2); if (is_fc) { /* FCP-2 ANSI INCITS.350:2003 */ scsi_ulto2b(0x0917, inq_ptr->version3); } else { /* SPI-4 ANSI INCITS.362:200x */ scsi_ulto2b(0x0B56, inq_ptr->version3); } if (lun == NULL) { /* SBC-2 (no version claimed) XXX should we claim a version? */ scsi_ulto2b(0x0320, inq_ptr->version4); } else { switch (lun->be_lun->lun_type) { case T_DIRECT: /* * SBC-2 (no version claimed) XXX should we claim a * version? */ scsi_ulto2b(0x0320, inq_ptr->version4); break; case T_PROCESSOR: default: break; } } ctsio->scsi_status = SCSI_STATUS_OK; if (ctsio->kern_data_len > 0) { ctsio->be_move_done = ctl_config_move_done; ctl_datamove((union ctl_io *)ctsio); } else { ctsio->io_hdr.status = CTL_SUCCESS; ctl_done((union ctl_io *)ctsio); } return (CTL_RETVAL_COMPLETE); } int ctl_inquiry(struct ctl_scsiio *ctsio) { struct scsi_inquiry *cdb; int retval; cdb = (struct scsi_inquiry *)ctsio->cdb; retval = 0; CTL_DEBUG_PRINT(("ctl_inquiry\n")); /* * Right now, we don't support the CmdDt inquiry information. * This would be nice to support in the future. When we do * support it, we should change this test so that it checks to make * sure SI_EVPD and SI_CMDDT aren't both set at the same time. */ #ifdef notyet if (((cdb->byte2 & SI_EVPD) && (cdb->byte2 & SI_CMDDT))) #endif if (cdb->byte2 & SI_CMDDT) { /* * Point to the SI_CMDDT bit. We might change this * when we support SI_CMDDT, but since both bits would be * "wrong", this should probably just stay as-is then. */ ctl_set_invalid_field(ctsio, /*sks_valid*/ 1, /*command*/ 1, /*field*/ 1, /*bit_valid*/ 1, /*bit*/ 1); ctl_done((union ctl_io *)ctsio); return (CTL_RETVAL_COMPLETE); } if (cdb->byte2 & SI_EVPD) retval = ctl_inquiry_evpd(ctsio); #ifdef notyet else if (cdb->byte2 & SI_CMDDT) retval = ctl_inquiry_cmddt(ctsio); #endif else retval = ctl_inquiry_std(ctsio); return (retval); } /* * For known CDB types, parse the LBA and length. */ static int ctl_get_lba_len(union ctl_io *io, uint64_t *lba, uint32_t *len) { if (io->io_hdr.io_type != CTL_IO_SCSI) return (1); switch (io->scsiio.cdb[0]) { case READ_6: case WRITE_6: { struct scsi_rw_6 *cdb; cdb = (struct scsi_rw_6 *)io->scsiio.cdb; *lba = scsi_3btoul(cdb->addr); /* only 5 bits are valid in the most significant address byte */ *lba &= 0x1fffff; *len = cdb->length; break; } case READ_10: case WRITE_10: { struct scsi_rw_10 *cdb; cdb = (struct scsi_rw_10 *)io->scsiio.cdb; *lba = scsi_4btoul(cdb->addr); *len = scsi_2btoul(cdb->length); break; } case WRITE_VERIFY_10: { struct scsi_write_verify_10 *cdb; cdb = (struct scsi_write_verify_10 *)io->scsiio.cdb; *lba = scsi_4btoul(cdb->addr); *len = scsi_2btoul(cdb->length); break; } case READ_12: case WRITE_12: { struct scsi_rw_12 *cdb; cdb = (struct scsi_rw_12 *)io->scsiio.cdb; *lba = scsi_4btoul(cdb->addr); *len = scsi_4btoul(cdb->length); break; } case WRITE_VERIFY_12: { struct scsi_write_verify_12 *cdb; cdb = (struct scsi_write_verify_12 *)io->scsiio.cdb; *lba = scsi_4btoul(cdb->addr); *len = scsi_4btoul(cdb->length); break; } case READ_16: case WRITE_16: { struct scsi_rw_16 *cdb; cdb = (struct scsi_rw_16 *)io->scsiio.cdb; *lba = scsi_8btou64(cdb->addr); *len = scsi_4btoul(cdb->length); break; } case WRITE_VERIFY_16: { struct scsi_write_verify_16 *cdb; cdb = (struct scsi_write_verify_16 *)io->scsiio.cdb; *lba = scsi_8btou64(cdb->addr); *len = scsi_4btoul(cdb->length); break; } default: return (1); break; /* NOTREACHED */ } return (0); } static ctl_action ctl_extent_check_lba(uint64_t lba1, uint32_t len1, uint64_t lba2, uint32_t len2) { uint64_t endlba1, endlba2; endlba1 = lba1 + len1 - 1; endlba2 = lba2 + len2 - 1; if ((endlba1 < lba2) || (endlba2 < lba1)) return (CTL_ACTION_PASS); else return (CTL_ACTION_BLOCK); } static ctl_action ctl_extent_check(union ctl_io *io1, union ctl_io *io2) { uint64_t lba1, lba2; uint32_t len1, len2; int retval; retval = ctl_get_lba_len(io1, &lba1, &len1); if (retval != 0) return (CTL_ACTION_ERROR); retval = ctl_get_lba_len(io2, &lba2, &len2); if (retval != 0) return (CTL_ACTION_ERROR); return (ctl_extent_check_lba(lba1, len1, lba2, len2)); } static ctl_action ctl_check_for_blockage(union ctl_io *pending_io, union ctl_io *ooa_io) { struct ctl_cmd_entry *pending_entry, *ooa_entry; ctl_serialize_action *serialize_row; /* * The initiator attempted multiple untagged commands at the same * time. Can't do that. */ if ((pending_io->scsiio.tag_type == CTL_TAG_UNTAGGED) && (ooa_io->scsiio.tag_type == CTL_TAG_UNTAGGED) && ((pending_io->io_hdr.nexus.targ_port == ooa_io->io_hdr.nexus.targ_port) && (pending_io->io_hdr.nexus.initid.id == ooa_io->io_hdr.nexus.initid.id)) && ((ooa_io->io_hdr.flags & CTL_FLAG_ABORT) == 0)) return (CTL_ACTION_OVERLAP); /* * The initiator attempted to send multiple tagged commands with * the same ID. (It's fine if different initiators have the same * tag ID.) * * Even if all of those conditions are true, we don't kill the I/O * if the command ahead of us has been aborted. We won't end up * sending it to the FETD, and it's perfectly legal to resend a * command with the same tag number as long as the previous * instance of this tag number has been aborted somehow. */ if ((pending_io->scsiio.tag_type != CTL_TAG_UNTAGGED) && (ooa_io->scsiio.tag_type != CTL_TAG_UNTAGGED) && (pending_io->scsiio.tag_num == ooa_io->scsiio.tag_num) && ((pending_io->io_hdr.nexus.targ_port == ooa_io->io_hdr.nexus.targ_port) && (pending_io->io_hdr.nexus.initid.id == ooa_io->io_hdr.nexus.initid.id)) && ((ooa_io->io_hdr.flags & CTL_FLAG_ABORT) == 0)) return (CTL_ACTION_OVERLAP_TAG); /* * If we get a head of queue tag, SAM-3 says that we should * immediately execute it. * * What happens if this command would normally block for some other * reason? e.g. a request sense with a head of queue tag * immediately after a write. Normally that would block, but this * will result in its getting executed immediately... * * We currently return "pass" instead of "skip", so we'll end up * going through the rest of the queue to check for overlapped tags. * * XXX KDM check for other types of blockage first?? */ if (pending_io->scsiio.tag_type == CTL_TAG_HEAD_OF_QUEUE) return (CTL_ACTION_PASS); /* * Ordered tags have to block until all items ahead of them * have completed. If we get called with an ordered tag, we always * block, if something else is ahead of us in the queue. */ if (pending_io->scsiio.tag_type == CTL_TAG_ORDERED) return (CTL_ACTION_BLOCK); /* * Simple tags get blocked until all head of queue and ordered tags * ahead of them have completed. I'm lumping untagged commands in * with simple tags here. XXX KDM is that the right thing to do? */ if (((pending_io->scsiio.tag_type == CTL_TAG_UNTAGGED) || (pending_io->scsiio.tag_type == CTL_TAG_SIMPLE)) && ((ooa_io->scsiio.tag_type == CTL_TAG_HEAD_OF_QUEUE) || (ooa_io->scsiio.tag_type == CTL_TAG_ORDERED))) return (CTL_ACTION_BLOCK); pending_entry = &ctl_cmd_table[pending_io->scsiio.cdb[0]]; ooa_entry = &ctl_cmd_table[ooa_io->scsiio.cdb[0]]; serialize_row = ctl_serialize_table[ooa_entry->seridx]; switch (serialize_row[pending_entry->seridx]) { case CTL_SER_BLOCK: return (CTL_ACTION_BLOCK); break; /* NOTREACHED */ case CTL_SER_EXTENT: return (ctl_extent_check(pending_io, ooa_io)); break; /* NOTREACHED */ case CTL_SER_PASS: return (CTL_ACTION_PASS); break; /* NOTREACHED */ case CTL_SER_SKIP: return (CTL_ACTION_SKIP); break; default: panic("invalid serialization value %d", serialize_row[pending_entry->seridx]); break; /* NOTREACHED */ } return (CTL_ACTION_ERROR); } /* * Check for blockage or overlaps against the OOA (Order Of Arrival) queue. * Assumptions: * - caller holds ctl_lock * - pending_io is generally either incoming, or on the blocked queue * - starting I/O is the I/O we want to start the check with. */ static ctl_action ctl_check_ooa(struct ctl_lun *lun, union ctl_io *pending_io, union ctl_io *starting_io) { union ctl_io *ooa_io; ctl_action action; /* * Run back along the OOA queue, starting with the current * blocked I/O and going through every I/O before it on the * queue. If starting_io is NULL, we'll just end up returning * CTL_ACTION_PASS. */ for (ooa_io = starting_io; ooa_io != NULL; ooa_io = (union ctl_io *)TAILQ_PREV(&ooa_io->io_hdr, ctl_ooaq, ooa_links)){ /* * This routine just checks to see whether * cur_blocked is blocked by ooa_io, which is ahead * of it in the queue. It doesn't queue/dequeue * cur_blocked. */ action = ctl_check_for_blockage(pending_io, ooa_io); switch (action) { case CTL_ACTION_BLOCK: case CTL_ACTION_OVERLAP: case CTL_ACTION_OVERLAP_TAG: case CTL_ACTION_SKIP: case CTL_ACTION_ERROR: return (action); break; /* NOTREACHED */ case CTL_ACTION_PASS: break; default: panic("invalid action %d", action); break; /* NOTREACHED */ } } return (CTL_ACTION_PASS); } /* * Assumptions: * - An I/O has just completed, and has been removed from the per-LUN OOA * queue, so some items on the blocked queue may now be unblocked. * - The caller holds ctl_softc->ctl_lock */ static int ctl_check_blocked(struct ctl_lun *lun) { union ctl_io *cur_blocked, *next_blocked; /* * Run forward from the head of the blocked queue, checking each * entry against the I/Os prior to it on the OOA queue to see if * there is still any blockage. * * We cannot use the TAILQ_FOREACH() macro, because it can't deal * with our removing a variable on it while it is traversing the * list. */ for (cur_blocked = (union ctl_io *)TAILQ_FIRST(&lun->blocked_queue); cur_blocked != NULL; cur_blocked = next_blocked) { union ctl_io *prev_ooa; ctl_action action; next_blocked = (union ctl_io *)TAILQ_NEXT(&cur_blocked->io_hdr, blocked_links); prev_ooa = (union ctl_io *)TAILQ_PREV(&cur_blocked->io_hdr, ctl_ooaq, ooa_links); /* * If cur_blocked happens to be the first item in the OOA * queue now, prev_ooa will be NULL, and the action * returned will just be CTL_ACTION_PASS. */ action = ctl_check_ooa(lun, cur_blocked, prev_ooa); switch (action) { case CTL_ACTION_BLOCK: /* Nothing to do here, still blocked */ break; case CTL_ACTION_OVERLAP: case CTL_ACTION_OVERLAP_TAG: /* * This shouldn't happen! In theory we've already * checked this command for overlap... */ break; case CTL_ACTION_PASS: case CTL_ACTION_SKIP: { struct ctl_softc *softc; struct ctl_cmd_entry *entry; uint32_t initidx; uint8_t opcode; int isc_retval; /* * The skip case shouldn't happen, this transaction * should have never made it onto the blocked queue. */ /* * This I/O is no longer blocked, we can remove it * from the blocked queue. Since this is a TAILQ * (doubly linked list), we can do O(1) removals * from any place on the list. */ TAILQ_REMOVE(&lun->blocked_queue, &cur_blocked->io_hdr, blocked_links); cur_blocked->io_hdr.flags &= ~CTL_FLAG_BLOCKED; if (cur_blocked->io_hdr.flags & CTL_FLAG_FROM_OTHER_SC){ /* * Need to send IO back to original side to * run */ union ctl_ha_msg msg_info; msg_info.hdr.original_sc = cur_blocked->io_hdr.original_sc; msg_info.hdr.serializing_sc = cur_blocked; msg_info.hdr.msg_type = CTL_MSG_R2R; if ((isc_retval=ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg_info, sizeof(msg_info), 0)) > CTL_HA_STATUS_SUCCESS) { printf("CTL:Check Blocked error from " "ctl_ha_msg_send %d\n", isc_retval); } break; } opcode = cur_blocked->scsiio.cdb[0]; entry = &ctl_cmd_table[opcode]; softc = control_softc; initidx = ctl_get_initindex(&cur_blocked->io_hdr.nexus); /* * Check this I/O for LUN state changes that may * have happened while this command was blocked. * The LUN state may have been changed by a command * ahead of us in the queue, so we need to re-check * for any states that can be caused by SCSI * commands. */ if (ctl_scsiio_lun_check(softc, lun, entry, &cur_blocked->scsiio) == 0) { cur_blocked->io_hdr.flags |= CTL_FLAG_IS_WAS_ON_RTR; STAILQ_INSERT_TAIL(&lun->ctl_softc->rtr_queue, &cur_blocked->io_hdr, links); /* * In the non CTL_DONE_THREAD case, we need * to wake up the work thread here. When * we're processing completed requests from * the work thread context, we'll pop back * around and end up pulling things off the * RtR queue. When we aren't processing * things from the work thread context, * though, we won't ever check the RtR queue. * So we need to wake up the thread to clear * things off the queue. Otherwise this * transaction will just sit on the RtR queue * until a new I/O comes in. (Which may or * may not happen...) */ #ifndef CTL_DONE_THREAD ctl_wakeup_thread(); #endif } else ctl_done_lock(cur_blocked, /*have_lock*/ 1); break; } default: /* * This probably shouldn't happen -- we shouldn't * get CTL_ACTION_ERROR, or anything else. */ break; } } return (CTL_RETVAL_COMPLETE); } /* * This routine (with one exception) checks LUN flags that can be set by * commands ahead of us in the OOA queue. These flags have to be checked * when a command initially comes in, and when we pull a command off the * blocked queue and are preparing to execute it. The reason we have to * check these flags for commands on the blocked queue is that the LUN * state may have been changed by a command ahead of us while we're on the * blocked queue. * * Ordering is somewhat important with these checks, so please pay * careful attention to the placement of any new checks. */ static int ctl_scsiio_lun_check(struct ctl_softc *ctl_softc, struct ctl_lun *lun, struct ctl_cmd_entry *entry, struct ctl_scsiio *ctsio) { int retval; retval = 0; /* * If this shelf is a secondary shelf controller, we have to reject * any media access commands. */ #if 0 /* No longer needed for HA */ if (((ctl_softc->flags & CTL_FLAG_MASTER_SHELF) == 0) && ((entry->flags & CTL_CMD_FLAG_OK_ON_SECONDARY) == 0)) { ctl_set_lun_standby(ctsio); retval = 1; goto bailout; } #endif /* * Check for a reservation conflict. If this command isn't allowed * even on reserved LUNs, and if this initiator isn't the one who * reserved us, reject the command with a reservation conflict. */ if ((lun->flags & CTL_LUN_RESERVED) && ((entry->flags & CTL_CMD_FLAG_ALLOW_ON_RESV) == 0)) { if ((ctsio->io_hdr.nexus.initid.id != lun->rsv_nexus.initid.id) || (ctsio->io_hdr.nexus.targ_port != lun->rsv_nexus.targ_port) || (ctsio->io_hdr.nexus.targ_target.id != lun->rsv_nexus.targ_target.id)) { ctsio->scsi_status = SCSI_STATUS_RESERV_CONFLICT; ctsio->io_hdr.status = CTL_SCSI_ERROR; retval = 1; goto bailout; } } if ( (lun->flags & CTL_LUN_PR_RESERVED) && ((entry->flags & CTL_CMD_FLAG_ALLOW_ON_PR_RESV) == 0)) { uint32_t residx; residx = ctl_get_resindex(&ctsio->io_hdr.nexus); /* * if we aren't registered or it's a res holder type * reservation and this isn't the res holder then set a * conflict. * NOTE: Commands which might be allowed on write exclusive * type reservations are checked in the particular command * for a conflict. Read and SSU are the only ones. */ if (!lun->per_res[residx].registered || (residx != lun->pr_res_idx && lun->res_type < 4)) { ctsio->scsi_status = SCSI_STATUS_RESERV_CONFLICT; ctsio->io_hdr.status = CTL_SCSI_ERROR; retval = 1; goto bailout; } } if ((lun->flags & CTL_LUN_OFFLINE) && ((entry->flags & CTL_CMD_FLAG_OK_ON_OFFLINE) == 0)) { ctl_set_lun_not_ready(ctsio); retval = 1; goto bailout; } /* * If the LUN is stopped, see if this particular command is allowed * for a stopped lun. Otherwise, reject it with 0x04,0x02. */ if ((lun->flags & CTL_LUN_STOPPED) && ((entry->flags & CTL_CMD_FLAG_OK_ON_STOPPED) == 0)) { /* "Logical unit not ready, initializing cmd. required" */ ctl_set_lun_stopped(ctsio); retval = 1; goto bailout; } if ((lun->flags & CTL_LUN_INOPERABLE) && ((entry->flags & CTL_CMD_FLAG_OK_ON_INOPERABLE) == 0)) { /* "Medium format corrupted" */ ctl_set_medium_format_corrupted(ctsio); retval = 1; goto bailout; } bailout: return (retval); } static void ctl_failover_io(union ctl_io *io, int have_lock) { ctl_set_busy(&io->scsiio); ctl_done_lock(io, have_lock); } static void ctl_failover(void) { struct ctl_lun *lun; struct ctl_softc *ctl_softc; union ctl_io *next_io, *pending_io; union ctl_io *io; int lun_idx; int i; ctl_softc = control_softc; mtx_lock(&ctl_softc->ctl_lock); /* * Remove any cmds from the other SC from the rtr queue. These * will obviously only be for LUNs for which we're the primary. * We can't send status or get/send data for these commands. * Since they haven't been executed yet, we can just remove them. * We'll either abort them or delete them below, depending on * which HA mode we're in. */ for (io = (union ctl_io *)STAILQ_FIRST(&ctl_softc->rtr_queue); io != NULL; io = next_io) { next_io = (union ctl_io *)STAILQ_NEXT(&io->io_hdr, links); if (io->io_hdr.flags & CTL_FLAG_FROM_OTHER_SC) STAILQ_REMOVE(&ctl_softc->rtr_queue, &io->io_hdr, ctl_io_hdr, links); } for (lun_idx=0; lun_idx < ctl_softc->num_luns; lun_idx++) { lun = ctl_softc->ctl_luns[lun_idx]; if (lun==NULL) continue; /* * Processor LUNs are primary on both sides. * XXX will this always be true? */ if (lun->be_lun->lun_type == T_PROCESSOR) continue; if ((lun->flags & CTL_LUN_PRIMARY_SC) && (ctl_softc->ha_mode == CTL_HA_MODE_SER_ONLY)) { printf("FAILOVER: primary lun %d\n", lun_idx); /* * Remove all commands from the other SC. First from the * blocked queue then from the ooa queue. Once we have * removed them. Call ctl_check_blocked to see if there * is anything that can run. */ for (io = (union ctl_io *)TAILQ_FIRST( &lun->blocked_queue); io != NULL; io = next_io) { next_io = (union ctl_io *)TAILQ_NEXT( &io->io_hdr, blocked_links); if (io->io_hdr.flags & CTL_FLAG_FROM_OTHER_SC) { TAILQ_REMOVE(&lun->blocked_queue, &io->io_hdr,blocked_links); io->io_hdr.flags &= ~CTL_FLAG_BLOCKED; TAILQ_REMOVE(&lun->ooa_queue, &io->io_hdr, ooa_links); ctl_free_io_internal(io, 1); } } for (io = (union ctl_io *)TAILQ_FIRST(&lun->ooa_queue); io != NULL; io = next_io) { next_io = (union ctl_io *)TAILQ_NEXT( &io->io_hdr, ooa_links); if (io->io_hdr.flags & CTL_FLAG_FROM_OTHER_SC) { TAILQ_REMOVE(&lun->ooa_queue, &io->io_hdr, ooa_links); ctl_free_io_internal(io, 1); } } ctl_check_blocked(lun); } else if ((lun->flags & CTL_LUN_PRIMARY_SC) && (ctl_softc->ha_mode == CTL_HA_MODE_XFER)) { printf("FAILOVER: primary lun %d\n", lun_idx); /* * Abort all commands from the other SC. We can't * send status back for them now. These should get * cleaned up when they are completed or come out * for a datamove operation. */ for (io = (union ctl_io *)TAILQ_FIRST(&lun->ooa_queue); io != NULL; io = next_io) { next_io = (union ctl_io *)TAILQ_NEXT( &io->io_hdr, ooa_links); if (io->io_hdr.flags & CTL_FLAG_FROM_OTHER_SC) io->io_hdr.flags |= CTL_FLAG_ABORT; } } else if (((lun->flags & CTL_LUN_PRIMARY_SC) == 0) && (ctl_softc->ha_mode == CTL_HA_MODE_XFER)) { printf("FAILOVER: secondary lun %d\n", lun_idx); lun->flags |= CTL_LUN_PRIMARY_SC; /* * We send all I/O that was sent to this controller * and redirected to the other side back with * busy status, and have the initiator retry it. * Figuring out how much data has been transferred, * etc. and picking up where we left off would be * very tricky. * * XXX KDM need to remove I/O from the blocked * queue as well! */ for (pending_io = (union ctl_io *)TAILQ_FIRST( &lun->ooa_queue); pending_io != NULL; pending_io = next_io) { next_io = (union ctl_io *)TAILQ_NEXT( &pending_io->io_hdr, ooa_links); pending_io->io_hdr.flags &= ~CTL_FLAG_SENT_2OTHER_SC; if (pending_io->io_hdr.flags & CTL_FLAG_IO_ACTIVE) { pending_io->io_hdr.flags |= CTL_FLAG_FAILOVER; } else { ctl_set_busy(&pending_io->scsiio); ctl_done_lock(pending_io, /*have_lock*/1); } } /* * Build Unit Attention */ for (i = 0; i < CTL_MAX_INITIATORS; i++) { lun->pending_sense[i].ua_pending |= CTL_UA_ASYM_ACC_CHANGE; } } else if (((lun->flags & CTL_LUN_PRIMARY_SC) == 0) && (ctl_softc->ha_mode == CTL_HA_MODE_SER_ONLY)) { printf("FAILOVER: secondary lun %d\n", lun_idx); /* * if the first io on the OOA is not on the RtR queue * add it. */ lun->flags |= CTL_LUN_PRIMARY_SC; pending_io = (union ctl_io *)TAILQ_FIRST( &lun->ooa_queue); if (pending_io==NULL) { printf("Nothing on OOA queue\n"); continue; } pending_io->io_hdr.flags &= ~CTL_FLAG_SENT_2OTHER_SC; if ((pending_io->io_hdr.flags & CTL_FLAG_IS_WAS_ON_RTR) == 0) { pending_io->io_hdr.flags |= CTL_FLAG_IS_WAS_ON_RTR; STAILQ_INSERT_TAIL(&ctl_softc->rtr_queue, &pending_io->io_hdr, links); } #if 0 else { printf("Tag 0x%04x is running\n", pending_io->scsiio.tag_num); } #endif next_io = (union ctl_io *)TAILQ_NEXT( &pending_io->io_hdr, ooa_links); for (pending_io=next_io; pending_io != NULL; pending_io = next_io) { pending_io->io_hdr.flags &= ~CTL_FLAG_SENT_2OTHER_SC; next_io = (union ctl_io *)TAILQ_NEXT( &pending_io->io_hdr, ooa_links); if (pending_io->io_hdr.flags & CTL_FLAG_IS_WAS_ON_RTR) { #if 0 printf("Tag 0x%04x is running\n", pending_io->scsiio.tag_num); #endif continue; } switch (ctl_check_ooa(lun, pending_io, (union ctl_io *)TAILQ_PREV( &pending_io->io_hdr, ctl_ooaq, ooa_links))) { case CTL_ACTION_BLOCK: TAILQ_INSERT_TAIL(&lun->blocked_queue, &pending_io->io_hdr, blocked_links); pending_io->io_hdr.flags |= CTL_FLAG_BLOCKED; break; case CTL_ACTION_PASS: case CTL_ACTION_SKIP: pending_io->io_hdr.flags |= CTL_FLAG_IS_WAS_ON_RTR; STAILQ_INSERT_TAIL( &ctl_softc->rtr_queue, &pending_io->io_hdr, links); break; case CTL_ACTION_OVERLAP: ctl_set_overlapped_cmd( (struct ctl_scsiio *)pending_io); ctl_done_lock(pending_io, /*have_lock*/ 1); break; case CTL_ACTION_OVERLAP_TAG: ctl_set_overlapped_tag( (struct ctl_scsiio *)pending_io, pending_io->scsiio.tag_num & 0xff); ctl_done_lock(pending_io, /*have_lock*/ 1); break; case CTL_ACTION_ERROR: default: ctl_set_internal_failure( (struct ctl_scsiio *)pending_io, 0, // sks_valid 0); //retry count ctl_done_lock(pending_io, /*have_lock*/ 1); break; } } /* * Build Unit Attention */ for (i = 0; i < CTL_MAX_INITIATORS; i++) { lun->pending_sense[i].ua_pending |= CTL_UA_ASYM_ACC_CHANGE; } } else { panic("Unhandled HA mode failover, LUN flags = %#x, " "ha_mode = #%x", lun->flags, ctl_softc->ha_mode); } } ctl_pause_rtr = 0; mtx_unlock(&ctl_softc->ctl_lock); } static int ctl_scsiio_precheck(struct ctl_softc *ctl_softc, struct ctl_scsiio *ctsio) { struct ctl_lun *lun; struct ctl_cmd_entry *entry; uint8_t opcode; uint32_t initidx; int retval; retval = 0; lun = NULL; opcode = ctsio->cdb[0]; mtx_lock(&ctl_softc->ctl_lock); if ((ctsio->io_hdr.nexus.targ_lun < CTL_MAX_LUNS) && (ctl_softc->ctl_luns[ctsio->io_hdr.nexus.targ_lun] != NULL)) { lun = ctl_softc->ctl_luns[ctsio->io_hdr.nexus.targ_lun]; /* * If the LUN is invalid, pretend that it doesn't exist. * It will go away as soon as all pending I/O has been * completed. */ if (lun->flags & CTL_LUN_DISABLED) { lun = NULL; } else { ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr = lun; ctsio->io_hdr.ctl_private[CTL_PRIV_BACKEND_LUN].ptr = lun->be_lun; if (lun->be_lun->lun_type == T_PROCESSOR) { ctsio->io_hdr.flags |= CTL_FLAG_CONTROL_DEV; } } } else { ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr = NULL; ctsio->io_hdr.ctl_private[CTL_PRIV_BACKEND_LUN].ptr = NULL; } entry = &ctl_cmd_table[opcode]; ctsio->io_hdr.flags &= ~CTL_FLAG_DATA_MASK; ctsio->io_hdr.flags |= entry->flags & CTL_FLAG_DATA_MASK; /* * Check to see whether we can send this command to LUNs that don't * exist. This should pretty much only be the case for inquiry * and request sense. Further checks, below, really require having * a LUN, so we can't really check the command anymore. Just put * it on the rtr queue. */ if (lun == NULL) { if (entry->flags & CTL_CMD_FLAG_OK_ON_ALL_LUNS) goto queue_rtr; ctl_set_unsupported_lun(ctsio); mtx_unlock(&ctl_softc->ctl_lock); ctl_done((union ctl_io *)ctsio); goto bailout; } else { /* * Every I/O goes into the OOA queue for a particular LUN, and * stays there until completion. */ TAILQ_INSERT_TAIL(&lun->ooa_queue, &ctsio->io_hdr, ooa_links); /* * Make sure we support this particular command on this LUN. * e.g., we don't support writes to the control LUN. */ switch (lun->be_lun->lun_type) { case T_PROCESSOR: if (((entry->flags & CTL_CMD_FLAG_OK_ON_PROC) == 0) && ((entry->flags & CTL_CMD_FLAG_OK_ON_ALL_LUNS) == 0)) { ctl_set_invalid_opcode(ctsio); mtx_unlock(&ctl_softc->ctl_lock); ctl_done((union ctl_io *)ctsio); goto bailout; } break; case T_DIRECT: if (((entry->flags & CTL_CMD_FLAG_OK_ON_SLUN) == 0) && ((entry->flags & CTL_CMD_FLAG_OK_ON_ALL_LUNS) == 0)){ ctl_set_invalid_opcode(ctsio); mtx_unlock(&ctl_softc->ctl_lock); ctl_done((union ctl_io *)ctsio); goto bailout; } break; default: printf("Unsupported CTL LUN type %d\n", lun->be_lun->lun_type); panic("Unsupported CTL LUN type %d\n", lun->be_lun->lun_type); break; /* NOTREACHED */ } } initidx = ctl_get_initindex(&ctsio->io_hdr.nexus); /* * If we've got a request sense, it'll clear the contingent * allegiance condition. Otherwise, if we have a CA condition for * this initiator, clear it, because it sent down a command other * than request sense. */ if ((opcode != REQUEST_SENSE) && (ctl_is_set(lun->have_ca, initidx))) ctl_clear_mask(lun->have_ca, initidx); /* * If the command has this flag set, it handles its own unit * attention reporting, we shouldn't do anything. Otherwise we * check for any pending unit attentions, and send them back to the * initiator. We only do this when a command initially comes in, * not when we pull it off the blocked queue. * * According to SAM-3, section 5.3.2, the order that things get * presented back to the host is basically unit attentions caused * by some sort of reset event, busy status, reservation conflicts * or task set full, and finally any other status. * * One issue here is that some of the unit attentions we report * don't fall into the "reset" category (e.g. "reported luns data * has changed"). So reporting it here, before the reservation * check, may be technically wrong. I guess the only thing to do * would be to check for and report the reset events here, and then * check for the other unit attention types after we check for a * reservation conflict. * * XXX KDM need to fix this */ if ((entry->flags & CTL_CMD_FLAG_NO_SENSE) == 0) { ctl_ua_type ua_type; ua_type = lun->pending_sense[initidx].ua_pending; if (ua_type != CTL_UA_NONE) { scsi_sense_data_type sense_format; if (lun != NULL) sense_format = (lun->flags & CTL_LUN_SENSE_DESC) ? SSD_TYPE_DESC : SSD_TYPE_FIXED; else sense_format = SSD_TYPE_FIXED; ua_type = ctl_build_ua(ua_type, &ctsio->sense_data, sense_format); if (ua_type != CTL_UA_NONE) { ctsio->scsi_status = SCSI_STATUS_CHECK_COND; ctsio->io_hdr.status = CTL_SCSI_ERROR | CTL_AUTOSENSE; ctsio->sense_len = SSD_FULL_SIZE; lun->pending_sense[initidx].ua_pending &= ~ua_type; mtx_unlock(&ctl_softc->ctl_lock); ctl_done((union ctl_io *)ctsio); goto bailout; } } } if (ctl_scsiio_lun_check(ctl_softc, lun, entry, ctsio) != 0) { mtx_unlock(&ctl_softc->ctl_lock); ctl_done((union ctl_io *)ctsio); goto bailout; } /* * XXX CHD this is where we want to send IO to other side if * this LUN is secondary on this SC. We will need to make a copy * of the IO and flag the IO on this side as SENT_2OTHER and the flag * the copy we send as FROM_OTHER. * We also need to stuff the address of the original IO so we can * find it easily. Something similar will need be done on the other * side so when we are done we can find the copy. */ if ((lun->flags & CTL_LUN_PRIMARY_SC) == 0) { union ctl_ha_msg msg_info; int isc_retval; ctsio->io_hdr.flags |= CTL_FLAG_SENT_2OTHER_SC; msg_info.hdr.msg_type = CTL_MSG_SERIALIZE; msg_info.hdr.original_sc = (union ctl_io *)ctsio; #if 0 printf("1. ctsio %p\n", ctsio); #endif msg_info.hdr.serializing_sc = NULL; msg_info.hdr.nexus = ctsio->io_hdr.nexus; msg_info.scsi.tag_num = ctsio->tag_num; msg_info.scsi.tag_type = ctsio->tag_type; memcpy(msg_info.scsi.cdb, ctsio->cdb, CTL_MAX_CDBLEN); ctsio->io_hdr.flags &= ~CTL_FLAG_IO_ACTIVE; if ((isc_retval=ctl_ha_msg_send(CTL_HA_CHAN_CTL, (void *)&msg_info, sizeof(msg_info), 0)) > CTL_HA_STATUS_SUCCESS) { printf("CTL:precheck, ctl_ha_msg_send returned %d\n", isc_retval); printf("CTL:opcode is %x\n",opcode); } else { #if 0 printf("CTL:Precheck sent msg, opcode is %x\n",opcode); #endif } /* * XXX KDM this I/O is off the incoming queue, but hasn't * been inserted on any other queue. We may need to come * up with a holding queue while we wait for serialization * so that we have an idea of what we're waiting for from * the other side. */ goto bailout_unlock; } switch (ctl_check_ooa(lun, (union ctl_io *)ctsio, (union ctl_io *)TAILQ_PREV(&ctsio->io_hdr, ctl_ooaq, ooa_links))) { case CTL_ACTION_BLOCK: ctsio->io_hdr.flags |= CTL_FLAG_BLOCKED; TAILQ_INSERT_TAIL(&lun->blocked_queue, &ctsio->io_hdr, blocked_links); goto bailout_unlock; break; /* NOTREACHED */ case CTL_ACTION_PASS: case CTL_ACTION_SKIP: goto queue_rtr; break; /* NOTREACHED */ case CTL_ACTION_OVERLAP: ctl_set_overlapped_cmd(ctsio); mtx_unlock(&ctl_softc->ctl_lock); ctl_done((union ctl_io *)ctsio); goto bailout; break; /* NOTREACHED */ case CTL_ACTION_OVERLAP_TAG: ctl_set_overlapped_tag(ctsio, ctsio->tag_num & 0xff); mtx_unlock(&ctl_softc->ctl_lock); ctl_done((union ctl_io *)ctsio); goto bailout; break; /* NOTREACHED */ case CTL_ACTION_ERROR: default: ctl_set_internal_failure(ctsio, /*sks_valid*/ 0, /*retry_count*/ 0); mtx_unlock(&ctl_softc->ctl_lock); ctl_done((union ctl_io *)ctsio); goto bailout; break; /* NOTREACHED */ } goto bailout_unlock; queue_rtr: ctsio->io_hdr.flags |= CTL_FLAG_IS_WAS_ON_RTR; STAILQ_INSERT_TAIL(&ctl_softc->rtr_queue, &ctsio->io_hdr, links); bailout_unlock: mtx_unlock(&ctl_softc->ctl_lock); bailout: return (retval); } static int ctl_scsiio(struct ctl_scsiio *ctsio) { int retval; struct ctl_cmd_entry *entry; retval = CTL_RETVAL_COMPLETE; CTL_DEBUG_PRINT(("ctl_scsiio cdb[0]=%02X\n", ctsio->cdb[0])); entry = &ctl_cmd_table[ctsio->cdb[0]]; /* * If this I/O has been aborted, just send it straight to * ctl_done() without executing it. */ if (ctsio->io_hdr.flags & CTL_FLAG_ABORT) { ctl_done((union ctl_io *)ctsio); goto bailout; } /* * All the checks should have been handled by ctl_scsiio_precheck(). * We should be clear now to just execute the I/O. */ retval = entry->execute(ctsio); bailout: return (retval); } /* * Since we only implement one target right now, a bus reset simply resets * our single target. */ static int ctl_bus_reset(struct ctl_softc *ctl_softc, union ctl_io *io) { return(ctl_target_reset(ctl_softc, io, CTL_UA_BUS_RESET)); } static int ctl_target_reset(struct ctl_softc *ctl_softc, union ctl_io *io, ctl_ua_type ua_type) { struct ctl_lun *lun; int retval; if (!(io->io_hdr.flags & CTL_FLAG_FROM_OTHER_SC)) { union ctl_ha_msg msg_info; io->io_hdr.flags |= CTL_FLAG_SENT_2OTHER_SC; msg_info.hdr.nexus = io->io_hdr.nexus; if (ua_type==CTL_UA_TARG_RESET) msg_info.task.task_action = CTL_TASK_TARGET_RESET; else msg_info.task.task_action = CTL_TASK_BUS_RESET; msg_info.hdr.msg_type = CTL_MSG_MANAGE_TASKS; msg_info.hdr.original_sc = NULL; msg_info.hdr.serializing_sc = NULL; if (CTL_HA_STATUS_SUCCESS != ctl_ha_msg_send(CTL_HA_CHAN_CTL, (void *)&msg_info, sizeof(msg_info), 0)) { } } retval = 0; STAILQ_FOREACH(lun, &ctl_softc->lun_list, links) retval += ctl_lun_reset(lun, io, ua_type); return (retval); } /* * The LUN should always be set. The I/O is optional, and is used to * distinguish between I/Os sent by this initiator, and by other * initiators. We set unit attention for initiators other than this one. * SAM-3 is vague on this point. It does say that a unit attention should * be established for other initiators when a LUN is reset (see section * 5.7.3), but it doesn't specifically say that the unit attention should * be established for this particular initiator when a LUN is reset. Here * is the relevant text, from SAM-3 rev 8: * * 5.7.2 When a SCSI initiator port aborts its own tasks * * When a SCSI initiator port causes its own task(s) to be aborted, no * notification that the task(s) have been aborted shall be returned to * the SCSI initiator port other than the completion response for the * command or task management function action that caused the task(s) to * be aborted and notification(s) associated with related effects of the * action (e.g., a reset unit attention condition). * * XXX KDM for now, we're setting unit attention for all initiators. */ static int ctl_lun_reset(struct ctl_lun *lun, union ctl_io *io, ctl_ua_type ua_type) { union ctl_io *xio; #if 0 uint32_t initindex; #endif int i; /* * Run through the OOA queue and abort each I/O. */ #if 0 TAILQ_FOREACH((struct ctl_io_hdr *)xio, &lun->ooa_queue, ooa_links) { #endif for (xio = (union ctl_io *)TAILQ_FIRST(&lun->ooa_queue); xio != NULL; xio = (union ctl_io *)TAILQ_NEXT(&xio->io_hdr, ooa_links)) { xio->io_hdr.flags |= CTL_FLAG_ABORT; } /* * This version sets unit attention for every */ #if 0 initindex = ctl_get_initindex(&io->io_hdr.nexus); for (i = 0; i < CTL_MAX_INITIATORS; i++) { if (initindex == i) continue; lun->pending_sense[i].ua_pending |= ua_type; } #endif /* * A reset (any kind, really) clears reservations established with * RESERVE/RELEASE. It does not clear reservations established * with PERSISTENT RESERVE OUT, but we don't support that at the * moment anyway. See SPC-2, section 5.6. SPC-3 doesn't address * reservations made with the RESERVE/RELEASE commands, because * those commands are obsolete in SPC-3. */ lun->flags &= ~CTL_LUN_RESERVED; for (i = 0; i < CTL_MAX_INITIATORS; i++) { ctl_clear_mask(lun->have_ca, i); lun->pending_sense[i].ua_pending |= ua_type; } return (0); } static int ctl_abort_task(union ctl_io *io) { union ctl_io *xio; struct ctl_lun *lun; struct ctl_softc *ctl_softc; #if 0 struct sbuf sb; char printbuf[128]; #endif int found; ctl_softc = control_softc; found = 0; /* * Look up the LUN. */ if ((io->io_hdr.nexus.targ_lun < CTL_MAX_LUNS) && (ctl_softc->ctl_luns[io->io_hdr.nexus.targ_lun] != NULL)) lun = ctl_softc->ctl_luns[io->io_hdr.nexus.targ_lun]; else goto bailout; #if 0 printf("ctl_abort_task: called for lun %lld, tag %d type %d\n", lun->lun, io->taskio.tag_num, io->taskio.tag_type); #endif /* * Run through the OOA queue and attempt to find the given I/O. * The target port, initiator ID, tag type and tag number have to * match the values that we got from the initiator. If we have an * untagged command to abort, simply abort the first untagged command * we come to. We only allow one untagged command at a time of course. */ #if 0 TAILQ_FOREACH((struct ctl_io_hdr *)xio, &lun->ooa_queue, ooa_links) { #endif for (xio = (union ctl_io *)TAILQ_FIRST(&lun->ooa_queue); xio != NULL; xio = (union ctl_io *)TAILQ_NEXT(&xio->io_hdr, ooa_links)) { #if 0 sbuf_new(&sb, printbuf, sizeof(printbuf), SBUF_FIXEDLEN); sbuf_printf(&sb, "LUN %lld tag %d type %d%s%s%s%s: ", lun->lun, xio->scsiio.tag_num, xio->scsiio.tag_type, (xio->io_hdr.blocked_links.tqe_prev == NULL) ? "" : " BLOCKED", (xio->io_hdr.flags & CTL_FLAG_DMA_INPROG) ? " DMA" : "", (xio->io_hdr.flags & CTL_FLAG_ABORT) ? " ABORT" : ""), (xio->io_hdr.flags & CTL_FLAG_IS_WAS_ON_RTR ? " RTR" : ""); ctl_scsi_command_string(&xio->scsiio, NULL, &sb); sbuf_finish(&sb); printf("%s\n", sbuf_data(&sb)); #endif if ((xio->io_hdr.nexus.targ_port == io->io_hdr.nexus.targ_port) && (xio->io_hdr.nexus.initid.id == io->io_hdr.nexus.initid.id)) { /* * If the abort says that the task is untagged, the * task in the queue must be untagged. Otherwise, * we just check to see whether the tag numbers * match. This is because the QLogic firmware * doesn't pass back the tag type in an abort * request. */ #if 0 if (((xio->scsiio.tag_type == CTL_TAG_UNTAGGED) && (io->taskio.tag_type == CTL_TAG_UNTAGGED)) || (xio->scsiio.tag_num == io->taskio.tag_num)) { #endif /* * XXX KDM we've got problems with FC, because it * doesn't send down a tag type with aborts. So we * can only really go by the tag number... * This may cause problems with parallel SCSI. * Need to figure that out!! */ if (xio->scsiio.tag_num == io->taskio.tag_num) { xio->io_hdr.flags |= CTL_FLAG_ABORT; found = 1; if ((io->io_hdr.flags & CTL_FLAG_FROM_OTHER_SC) == 0 && !(lun->flags & CTL_LUN_PRIMARY_SC)) { union ctl_ha_msg msg_info; io->io_hdr.flags |= CTL_FLAG_SENT_2OTHER_SC; msg_info.hdr.nexus = io->io_hdr.nexus; msg_info.task.task_action = CTL_TASK_ABORT_TASK; msg_info.task.tag_num = io->taskio.tag_num; msg_info.task.tag_type = io->taskio.tag_type; msg_info.hdr.msg_type = CTL_MSG_MANAGE_TASKS; msg_info.hdr.original_sc = NULL; msg_info.hdr.serializing_sc = NULL; #if 0 printf("Sent Abort to other side\n"); #endif if (CTL_HA_STATUS_SUCCESS != ctl_ha_msg_send(CTL_HA_CHAN_CTL, (void *)&msg_info, sizeof(msg_info), 0)) { } } #if 0 printf("ctl_abort_task: found I/O to abort\n"); #endif break; } } } bailout: if (found == 0) { /* * This isn't really an error. It's entirely possible for * the abort and command completion to cross on the wire. * This is more of an informative/diagnostic error. */ #if 0 printf("ctl_abort_task: ABORT sent for nonexistent I/O: " "%d:%d:%d:%d tag %d type %d\n", io->io_hdr.nexus.initid.id, io->io_hdr.nexus.targ_port, io->io_hdr.nexus.targ_target.id, io->io_hdr.nexus.targ_lun, io->taskio.tag_num, io->taskio.tag_type); #endif return (1); } else return (0); } /* * Assumptions: caller holds ctl_softc->ctl_lock * * This routine cannot block! It must be callable from an interrupt * handler as well as from the work thread. */ static void ctl_run_task_queue(struct ctl_softc *ctl_softc) { union ctl_io *io, *next_io; CTL_DEBUG_PRINT(("ctl_run_task_queue\n")); for (io = (union ctl_io *)STAILQ_FIRST(&ctl_softc->task_queue); io != NULL; io = next_io) { int retval; const char *task_desc; next_io = (union ctl_io *)STAILQ_NEXT(&io->io_hdr, links); retval = 0; switch (io->io_hdr.io_type) { case CTL_IO_TASK: { task_desc = ctl_scsi_task_string(&io->taskio); if (task_desc != NULL) { #ifdef NEEDTOPORT csevent_log(CSC_CTL | CSC_SHELF_SW | CTL_TASK_REPORT, csevent_LogType_Trace, csevent_Severity_Information, csevent_AlertLevel_Green, csevent_FRU_Firmware, csevent_FRU_Unknown, "CTL: received task: %s",task_desc); #endif } else { #ifdef NEEDTOPORT csevent_log(CSC_CTL | CSC_SHELF_SW | CTL_TASK_REPORT, csevent_LogType_Trace, csevent_Severity_Information, csevent_AlertLevel_Green, csevent_FRU_Firmware, csevent_FRU_Unknown, "CTL: received unknown task " "type: %d (%#x)", io->taskio.task_action, io->taskio.task_action); #endif } switch (io->taskio.task_action) { case CTL_TASK_ABORT_TASK: retval = ctl_abort_task(io); break; case CTL_TASK_ABORT_TASK_SET: break; case CTL_TASK_CLEAR_ACA: break; case CTL_TASK_CLEAR_TASK_SET: break; case CTL_TASK_LUN_RESET: { struct ctl_lun *lun; uint32_t targ_lun; int retval; targ_lun = io->io_hdr.nexus.targ_lun; if ((targ_lun < CTL_MAX_LUNS) && (ctl_softc->ctl_luns[targ_lun] != NULL)) lun = ctl_softc->ctl_luns[targ_lun]; else { retval = 1; break; } if (!(io->io_hdr.flags & CTL_FLAG_FROM_OTHER_SC)) { union ctl_ha_msg msg_info; io->io_hdr.flags |= CTL_FLAG_SENT_2OTHER_SC; msg_info.hdr.msg_type = CTL_MSG_MANAGE_TASKS; msg_info.hdr.nexus = io->io_hdr.nexus; msg_info.task.task_action = CTL_TASK_LUN_RESET; msg_info.hdr.original_sc = NULL; msg_info.hdr.serializing_sc = NULL; if (CTL_HA_STATUS_SUCCESS != ctl_ha_msg_send(CTL_HA_CHAN_CTL, (void *)&msg_info, sizeof(msg_info), 0)) { } } retval = ctl_lun_reset(lun, io, CTL_UA_LUN_RESET); break; } case CTL_TASK_TARGET_RESET: retval = ctl_target_reset(ctl_softc, io, CTL_UA_TARG_RESET); break; case CTL_TASK_BUS_RESET: retval = ctl_bus_reset(ctl_softc, io); break; case CTL_TASK_PORT_LOGIN: break; case CTL_TASK_PORT_LOGOUT: break; default: printf("ctl_run_task_queue: got unknown task " "management event %d\n", io->taskio.task_action); break; } if (retval == 0) io->io_hdr.status = CTL_SUCCESS; else io->io_hdr.status = CTL_ERROR; STAILQ_REMOVE(&ctl_softc->task_queue, &io->io_hdr, ctl_io_hdr, links); /* * This will queue this I/O to the done queue, but the * work thread won't be able to process it until we * return and the lock is released. */ ctl_done_lock(io, /*have_lock*/ 1); break; } default: { printf("%s: invalid I/O type %d msg %d cdb %x" " iptl: %ju:%d:%ju:%d tag 0x%04x\n", __func__, io->io_hdr.io_type, io->io_hdr.msg_type, io->scsiio.cdb[0], (uintmax_t)io->io_hdr.nexus.initid.id, io->io_hdr.nexus.targ_port, (uintmax_t)io->io_hdr.nexus.targ_target.id, io->io_hdr.nexus.targ_lun, (io->io_hdr.io_type == CTL_IO_TASK) ? io->taskio.tag_num : io->scsiio.tag_num); STAILQ_REMOVE(&ctl_softc->task_queue, &io->io_hdr, ctl_io_hdr, links); ctl_free_io_internal(io, 1); break; } } } ctl_softc->flags &= ~CTL_FLAG_TASK_PENDING; } /* * For HA operation. Handle commands that come in from the other * controller. */ static void ctl_handle_isc(union ctl_io *io) { int free_io; struct ctl_lun *lun; struct ctl_softc *ctl_softc; ctl_softc = control_softc; lun = ctl_softc->ctl_luns[io->io_hdr.nexus.targ_lun]; switch (io->io_hdr.msg_type) { case CTL_MSG_SERIALIZE: free_io = ctl_serialize_other_sc_cmd(&io->scsiio, /*have_lock*/ 0); break; case CTL_MSG_R2R: { uint8_t opcode; struct ctl_cmd_entry *entry; /* * This is only used in SER_ONLY mode. */ free_io = 0; opcode = io->scsiio.cdb[0]; entry = &ctl_cmd_table[opcode]; mtx_lock(&ctl_softc->ctl_lock); if (ctl_scsiio_lun_check(ctl_softc, lun, entry, (struct ctl_scsiio *)io) != 0) { ctl_done_lock(io, /*have_lock*/ 1); mtx_unlock(&ctl_softc->ctl_lock); break; } io->io_hdr.flags |= CTL_FLAG_IS_WAS_ON_RTR; STAILQ_INSERT_TAIL(&ctl_softc->rtr_queue, &io->io_hdr, links); mtx_unlock(&ctl_softc->ctl_lock); break; } case CTL_MSG_FINISH_IO: if (ctl_softc->ha_mode == CTL_HA_MODE_XFER) { free_io = 0; ctl_done_lock(io, /*have_lock*/ 0); } else { free_io = 1; mtx_lock(&ctl_softc->ctl_lock); TAILQ_REMOVE(&lun->ooa_queue, &io->io_hdr, ooa_links); STAILQ_REMOVE(&ctl_softc->task_queue, &io->io_hdr, ctl_io_hdr, links); ctl_check_blocked(lun); mtx_unlock(&ctl_softc->ctl_lock); } break; case CTL_MSG_PERS_ACTION: ctl_hndl_per_res_out_on_other_sc( (union ctl_ha_msg *)&io->presio.pr_msg); free_io = 1; break; case CTL_MSG_BAD_JUJU: free_io = 0; ctl_done_lock(io, /*have_lock*/ 0); break; case CTL_MSG_DATAMOVE: /* Only used in XFER mode */ free_io = 0; ctl_datamove_remote(io); break; case CTL_MSG_DATAMOVE_DONE: /* Only used in XFER mode */ free_io = 0; io->scsiio.be_move_done(io); break; default: free_io = 1; printf("%s: Invalid message type %d\n", __func__, io->io_hdr.msg_type); break; } if (free_io) ctl_free_io_internal(io, 0); } /* * Returns the match type in the case of a match, or CTL_LUN_PAT_NONE if * there is no match. */ static ctl_lun_error_pattern ctl_cmd_pattern_match(struct ctl_scsiio *ctsio, struct ctl_error_desc *desc) { struct ctl_cmd_entry *entry; ctl_lun_error_pattern filtered_pattern, pattern; uint8_t opcode; pattern = desc->error_pattern; /* * XXX KDM we need more data passed into this function to match a * custom pattern, and we actually need to implement custom pattern * matching. */ if (pattern & CTL_LUN_PAT_CMD) return (CTL_LUN_PAT_CMD); if ((pattern & CTL_LUN_PAT_MASK) == CTL_LUN_PAT_ANY) return (CTL_LUN_PAT_ANY); opcode = ctsio->cdb[0]; entry = &ctl_cmd_table[opcode]; filtered_pattern = entry->pattern & pattern; /* * If the user requested specific flags in the pattern (e.g. * CTL_LUN_PAT_RANGE), make sure the command supports all of those * flags. * * If the user did not specify any flags, it doesn't matter whether * or not the command supports the flags. */ if ((filtered_pattern & ~CTL_LUN_PAT_MASK) != (pattern & ~CTL_LUN_PAT_MASK)) return (CTL_LUN_PAT_NONE); /* * If the user asked for a range check, see if the requested LBA * range overlaps with this command's LBA range. */ if (filtered_pattern & CTL_LUN_PAT_RANGE) { uint64_t lba1; uint32_t len1; ctl_action action; int retval; retval = ctl_get_lba_len((union ctl_io *)ctsio, &lba1, &len1); if (retval != 0) return (CTL_LUN_PAT_NONE); action = ctl_extent_check_lba(lba1, len1, desc->lba_range.lba, desc->lba_range.len); /* * A "pass" means that the LBA ranges don't overlap, so * this doesn't match the user's range criteria. */ if (action == CTL_ACTION_PASS) return (CTL_LUN_PAT_NONE); } return (filtered_pattern); } /* * Called with the CTL lock held. */ static void ctl_inject_error(struct ctl_lun *lun, union ctl_io *io) { struct ctl_error_desc *desc, *desc2; STAILQ_FOREACH_SAFE(desc, &lun->error_list, links, desc2) { ctl_lun_error_pattern pattern; /* * Check to see whether this particular command matches * the pattern in the descriptor. */ pattern = ctl_cmd_pattern_match(&io->scsiio, desc); if ((pattern & CTL_LUN_PAT_MASK) == CTL_LUN_PAT_NONE) continue; switch (desc->lun_error & CTL_LUN_INJ_TYPE) { case CTL_LUN_INJ_ABORTED: ctl_set_aborted(&io->scsiio); break; case CTL_LUN_INJ_MEDIUM_ERR: ctl_set_medium_error(&io->scsiio); break; case CTL_LUN_INJ_UA: /* 29h/00h POWER ON, RESET, OR BUS DEVICE RESET * OCCURRED */ ctl_set_ua(&io->scsiio, 0x29, 0x00); break; case CTL_LUN_INJ_CUSTOM: /* * We're assuming the user knows what he is doing. * Just copy the sense information without doing * checks. */ bcopy(&desc->custom_sense, &io->scsiio.sense_data, ctl_min(sizeof(desc->custom_sense), sizeof(io->scsiio.sense_data))); io->scsiio.scsi_status = SCSI_STATUS_CHECK_COND; io->scsiio.sense_len = SSD_FULL_SIZE; io->io_hdr.status = CTL_SCSI_ERROR | CTL_AUTOSENSE; break; case CTL_LUN_INJ_NONE: default: /* * If this is an error injection type we don't know * about, clear the continuous flag (if it is set) * so it will get deleted below. */ desc->lun_error &= ~CTL_LUN_INJ_CONTINUOUS; break; } /* * By default, each error injection action is a one-shot */ if (desc->lun_error & CTL_LUN_INJ_CONTINUOUS) continue; STAILQ_REMOVE(&lun->error_list, desc, ctl_error_desc, links); free(desc, M_CTL); } } #ifdef CTL_IO_DELAY static void ctl_datamove_timer_wakeup(void *arg) { union ctl_io *io; io = (union ctl_io *)arg; ctl_datamove(io); } #endif /* CTL_IO_DELAY */ /* * Assumption: caller does NOT hold ctl_lock */ void ctl_datamove(union ctl_io *io) { void (*fe_datamove)(union ctl_io *io); CTL_DEBUG_PRINT(("ctl_datamove\n")); #ifdef CTL_TIME_IO if ((time_uptime - io->io_hdr.start_time) > ctl_time_io_secs) { char str[256]; char path_str[64]; struct sbuf sb; ctl_scsi_path_string(io, path_str, sizeof(path_str)); sbuf_new(&sb, str, sizeof(str), SBUF_FIXEDLEN); sbuf_cat(&sb, path_str); switch (io->io_hdr.io_type) { case CTL_IO_SCSI: ctl_scsi_command_string(&io->scsiio, NULL, &sb); sbuf_printf(&sb, "\n"); sbuf_cat(&sb, path_str); sbuf_printf(&sb, "Tag: 0x%04x, type %d\n", io->scsiio.tag_num, io->scsiio.tag_type); break; case CTL_IO_TASK: sbuf_printf(&sb, "Task I/O type: %d, Tag: 0x%04x, " "Tag Type: %d\n", io->taskio.task_action, io->taskio.tag_num, io->taskio.tag_type); break; default: printf("Invalid CTL I/O type %d\n", io->io_hdr.io_type); panic("Invalid CTL I/O type %d\n", io->io_hdr.io_type); break; } sbuf_cat(&sb, path_str); sbuf_printf(&sb, "ctl_datamove: %jd seconds\n", (intmax_t)time_uptime - io->io_hdr.start_time); sbuf_finish(&sb); printf("%s", sbuf_data(&sb)); } #endif /* CTL_TIME_IO */ mtx_lock(&control_softc->ctl_lock); #ifdef CTL_IO_DELAY if (io->io_hdr.flags & CTL_FLAG_DELAY_DONE) { struct ctl_lun *lun; lun =(struct ctl_lun *)io->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; io->io_hdr.flags &= ~CTL_FLAG_DELAY_DONE; } else { struct ctl_lun *lun; lun =(struct ctl_lun *)io->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; if ((lun != NULL) && (lun->delay_info.datamove_delay > 0)) { struct callout *callout; callout = (struct callout *)&io->io_hdr.timer_bytes; callout_init(callout, /*mpsafe*/ 1); io->io_hdr.flags |= CTL_FLAG_DELAY_DONE; callout_reset(callout, lun->delay_info.datamove_delay * hz, ctl_datamove_timer_wakeup, io); if (lun->delay_info.datamove_type == CTL_DELAY_TYPE_ONESHOT) lun->delay_info.datamove_delay = 0; mtx_unlock(&control_softc->ctl_lock); return; } } #endif /* * If we have any pending task management commands, process them * first. This is necessary to eliminate a race condition with the * FETD: * * - FETD submits a task management command, like an abort. * - Back end calls fe_datamove() to move the data for the aborted * command. The FETD can't really accept it, but if it did, it * would end up transmitting data for a command that the initiator * told us to abort. * * We close the race by processing all pending task management * commands here (we can't block!), and then check this I/O to see * if it has been aborted. If so, return it to the back end with * bad status, so the back end can say return an error to the back end * and then when the back end returns an error, we can return the * aborted command to the FETD, so it can clean up its resources. */ if (control_softc->flags & CTL_FLAG_TASK_PENDING) ctl_run_task_queue(control_softc); /* * This command has been aborted. Set the port status, so we fail * the data move. */ if (io->io_hdr.flags & CTL_FLAG_ABORT) { printf("ctl_datamove: tag 0x%04x on (%ju:%d:%ju:%d) aborted\n", io->scsiio.tag_num,(uintmax_t)io->io_hdr.nexus.initid.id, io->io_hdr.nexus.targ_port, (uintmax_t)io->io_hdr.nexus.targ_target.id, io->io_hdr.nexus.targ_lun); io->io_hdr.status = CTL_CMD_ABORTED; io->io_hdr.port_status = 31337; mtx_unlock(&control_softc->ctl_lock); /* * Note that the backend, in this case, will get the * callback in its context. In other cases it may get * called in the frontend's interrupt thread context. */ io->scsiio.be_move_done(io); return; } /* * If we're in XFER mode and this I/O is from the other shelf * controller, we need to send the DMA to the other side to * actually transfer the data to/from the host. In serialize only * mode the transfer happens below CTL and ctl_datamove() is only * called on the machine that originally received the I/O. */ if ((control_softc->ha_mode == CTL_HA_MODE_XFER) && (io->io_hdr.flags & CTL_FLAG_FROM_OTHER_SC)) { union ctl_ha_msg msg; uint32_t sg_entries_sent; int do_sg_copy; int i; memset(&msg, 0, sizeof(msg)); msg.hdr.msg_type = CTL_MSG_DATAMOVE; msg.hdr.original_sc = io->io_hdr.original_sc; msg.hdr.serializing_sc = io; msg.hdr.nexus = io->io_hdr.nexus; msg.dt.flags = io->io_hdr.flags; /* * We convert everything into a S/G list here. We can't * pass by reference, only by value between controllers. * So we can't pass a pointer to the S/G list, only as many * S/G entries as we can fit in here. If it's possible for * us to get more than CTL_HA_MAX_SG_ENTRIES S/G entries, * then we need to break this up into multiple transfers. */ if (io->scsiio.kern_sg_entries == 0) { msg.dt.kern_sg_entries = 1; /* * If this is in cached memory, flush the cache * before we send the DMA request to the other * controller. We want to do this in either the * read or the write case. The read case is * straightforward. In the write case, we want to * make sure nothing is in the local cache that * could overwrite the DMAed data. */ if ((io->io_hdr.flags & CTL_FLAG_NO_DATASYNC) == 0) { /* * XXX KDM use bus_dmamap_sync() here. */ } /* * Convert to a physical address if this is a * virtual address. */ if (io->io_hdr.flags & CTL_FLAG_BUS_ADDR) { msg.dt.sg_list[0].addr = io->scsiio.kern_data_ptr; } else { /* * XXX KDM use busdma here! */ #if 0 msg.dt.sg_list[0].addr = (void *) vtophys(io->scsiio.kern_data_ptr); #endif } msg.dt.sg_list[0].len = io->scsiio.kern_data_len; do_sg_copy = 0; } else { struct ctl_sg_entry *sgl; do_sg_copy = 1; msg.dt.kern_sg_entries = io->scsiio.kern_sg_entries; sgl = (struct ctl_sg_entry *)io->scsiio.kern_data_ptr; if ((io->io_hdr.flags & CTL_FLAG_NO_DATASYNC) == 0) { /* * XXX KDM use bus_dmamap_sync() here. */ } } msg.dt.kern_data_len = io->scsiio.kern_data_len; msg.dt.kern_total_len = io->scsiio.kern_total_len; msg.dt.kern_data_resid = io->scsiio.kern_data_resid; msg.dt.kern_rel_offset = io->scsiio.kern_rel_offset; msg.dt.sg_sequence = 0; /* * Loop until we've sent all of the S/G entries. On the * other end, we'll recompose these S/G entries into one * contiguous list before passing it to the */ for (sg_entries_sent = 0; sg_entries_sent < msg.dt.kern_sg_entries; msg.dt.sg_sequence++) { msg.dt.cur_sg_entries = ctl_min((sizeof(msg.dt.sg_list)/ sizeof(msg.dt.sg_list[0])), msg.dt.kern_sg_entries - sg_entries_sent); if (do_sg_copy != 0) { struct ctl_sg_entry *sgl; int j; sgl = (struct ctl_sg_entry *) io->scsiio.kern_data_ptr; /* * If this is in cached memory, flush the cache * before we send the DMA request to the other * controller. We want to do this in either * the * read or the write case. The read * case is straightforward. In the write * case, we want to make sure nothing is * in the local cache that could overwrite * the DMAed data. */ for (i = sg_entries_sent, j = 0; i < msg.dt.cur_sg_entries; i++, j++) { if ((io->io_hdr.flags & CTL_FLAG_NO_DATASYNC) == 0) { /* * XXX KDM use bus_dmamap_sync() */ } if ((io->io_hdr.flags & CTL_FLAG_BUS_ADDR) == 0) { /* * XXX KDM use busdma. */ #if 0 msg.dt.sg_list[j].addr =(void *) vtophys(sgl[i].addr); #endif } else { msg.dt.sg_list[j].addr = sgl[i].addr; } msg.dt.sg_list[j].len = sgl[i].len; } } sg_entries_sent += msg.dt.cur_sg_entries; if (sg_entries_sent >= msg.dt.kern_sg_entries) msg.dt.sg_last = 1; else msg.dt.sg_last = 0; /* * XXX KDM drop and reacquire the lock here? */ if (ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg, sizeof(msg), 0) > CTL_HA_STATUS_SUCCESS) { /* * XXX do something here. */ } msg.dt.sent_sg_entries = sg_entries_sent; } io->io_hdr.flags &= ~CTL_FLAG_IO_ACTIVE; if (io->io_hdr.flags & CTL_FLAG_FAILOVER) ctl_failover_io(io, /*have_lock*/ 1); } else { /* * Lookup the fe_datamove() function for this particular * front end. */ fe_datamove = control_softc->ctl_ports[ctl_port_idx(io->io_hdr.nexus.targ_port)]->fe_datamove; mtx_unlock(&control_softc->ctl_lock); fe_datamove(io); } } static void ctl_send_datamove_done(union ctl_io *io, int have_lock) { union ctl_ha_msg msg; int isc_status; memset(&msg, 0, sizeof(msg)); msg.hdr.msg_type = CTL_MSG_DATAMOVE_DONE; msg.hdr.original_sc = io; msg.hdr.serializing_sc = io->io_hdr.serializing_sc; msg.hdr.nexus = io->io_hdr.nexus; msg.hdr.status = io->io_hdr.status; msg.scsi.tag_num = io->scsiio.tag_num; msg.scsi.tag_type = io->scsiio.tag_type; msg.scsi.scsi_status = io->scsiio.scsi_status; memcpy(&msg.scsi.sense_data, &io->scsiio.sense_data, sizeof(io->scsiio.sense_data)); msg.scsi.sense_len = io->scsiio.sense_len; msg.scsi.sense_residual = io->scsiio.sense_residual; msg.scsi.fetd_status = io->io_hdr.port_status; msg.scsi.residual = io->scsiio.residual; io->io_hdr.flags &= ~CTL_FLAG_IO_ACTIVE; if (io->io_hdr.flags & CTL_FLAG_FAILOVER) { ctl_failover_io(io, /*have_lock*/ have_lock); return; } isc_status = ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg, sizeof(msg), 0); if (isc_status > CTL_HA_STATUS_SUCCESS) { /* XXX do something if this fails */ } } /* * The DMA to the remote side is done, now we need to tell the other side * we're done so it can continue with its data movement. */ static void ctl_datamove_remote_write_cb(struct ctl_ha_dt_req *rq) { union ctl_io *io; io = rq->context; if (rq->ret != CTL_HA_STATUS_SUCCESS) { printf("%s: ISC DMA write failed with error %d", __func__, rq->ret); ctl_set_internal_failure(&io->scsiio, /*sks_valid*/ 1, /*retry_count*/ rq->ret); } ctl_dt_req_free(rq); /* * In this case, we had to malloc the memory locally. Free it. */ if ((io->io_hdr.flags & CTL_FLAG_AUTO_MIRROR) == 0) { int i; for (i = 0; i < io->scsiio.kern_sg_entries; i++) free(io->io_hdr.local_sglist[i].addr, M_CTL); } /* * The data is in local and remote memory, so now we need to send * status (good or back) back to the other side. */ ctl_send_datamove_done(io, /*have_lock*/ 0); } /* * We've moved the data from the host/controller into local memory. Now we * need to push it over to the remote controller's memory. */ static int ctl_datamove_remote_dm_write_cb(union ctl_io *io) { int retval; retval = 0; retval = ctl_datamove_remote_xfer(io, CTL_HA_DT_CMD_WRITE, ctl_datamove_remote_write_cb); return (retval); } static void ctl_datamove_remote_write(union ctl_io *io) { int retval; void (*fe_datamove)(union ctl_io *io); /* * - Get the data from the host/HBA into local memory. * - DMA memory from the local controller to the remote controller. * - Send status back to the remote controller. */ retval = ctl_datamove_remote_sgl_setup(io); if (retval != 0) return; /* Switch the pointer over so the FETD knows what to do */ io->scsiio.kern_data_ptr = (uint8_t *)io->io_hdr.local_sglist; /* * Use a custom move done callback, since we need to send completion * back to the other controller, not to the backend on this side. */ io->scsiio.be_move_done = ctl_datamove_remote_dm_write_cb; fe_datamove = control_softc->ctl_ports[ctl_port_idx(io->io_hdr.nexus.targ_port)]->fe_datamove; fe_datamove(io); return; } static int ctl_datamove_remote_dm_read_cb(union ctl_io *io) { #if 0 char str[256]; char path_str[64]; struct sbuf sb; #endif /* * In this case, we had to malloc the memory locally. Free it. */ if ((io->io_hdr.flags & CTL_FLAG_AUTO_MIRROR) == 0) { int i; for (i = 0; i < io->scsiio.kern_sg_entries; i++) free(io->io_hdr.local_sglist[i].addr, M_CTL); } #if 0 scsi_path_string(io, path_str, sizeof(path_str)); sbuf_new(&sb, str, sizeof(str), SBUF_FIXEDLEN); sbuf_cat(&sb, path_str); scsi_command_string(&io->scsiio, NULL, &sb); sbuf_printf(&sb, "\n"); sbuf_cat(&sb, path_str); sbuf_printf(&sb, "Tag: 0x%04x, type %d\n", io->scsiio.tag_num, io->scsiio.tag_type); sbuf_cat(&sb, path_str); sbuf_printf(&sb, "%s: flags %#x, status %#x\n", __func__, io->io_hdr.flags, io->io_hdr.status); sbuf_finish(&sb); printk("%s", sbuf_data(&sb)); #endif /* * The read is done, now we need to send status (good or bad) back * to the other side. */ ctl_send_datamove_done(io, /*have_lock*/ 0); return (0); } static void ctl_datamove_remote_read_cb(struct ctl_ha_dt_req *rq) { union ctl_io *io; void (*fe_datamove)(union ctl_io *io); io = rq->context; if (rq->ret != CTL_HA_STATUS_SUCCESS) { printf("%s: ISC DMA read failed with error %d", __func__, rq->ret); ctl_set_internal_failure(&io->scsiio, /*sks_valid*/ 1, /*retry_count*/ rq->ret); } ctl_dt_req_free(rq); /* Switch the pointer over so the FETD knows what to do */ io->scsiio.kern_data_ptr = (uint8_t *)io->io_hdr.local_sglist; /* * Use a custom move done callback, since we need to send completion * back to the other controller, not to the backend on this side. */ io->scsiio.be_move_done = ctl_datamove_remote_dm_read_cb; /* XXX KDM add checks like the ones in ctl_datamove? */ fe_datamove = control_softc->ctl_ports[ctl_port_idx(io->io_hdr.nexus.targ_port)]->fe_datamove; fe_datamove(io); } static int ctl_datamove_remote_sgl_setup(union ctl_io *io) { struct ctl_sg_entry *local_sglist, *remote_sglist; struct ctl_sg_entry *local_dma_sglist, *remote_dma_sglist; struct ctl_softc *softc; int retval; int i; retval = 0; softc = control_softc; local_sglist = io->io_hdr.local_sglist; local_dma_sglist = io->io_hdr.local_dma_sglist; remote_sglist = io->io_hdr.remote_sglist; remote_dma_sglist = io->io_hdr.remote_dma_sglist; if (io->io_hdr.flags & CTL_FLAG_AUTO_MIRROR) { for (i = 0; i < io->scsiio.kern_sg_entries; i++) { local_sglist[i].len = remote_sglist[i].len; /* * XXX Detect the situation where the RS-level I/O * redirector on the other side has already read the * data off of the AOR RS on this side, and * transferred it to remote (mirror) memory on the * other side. Since we already have the data in * memory here, we just need to use it. * * XXX KDM this can probably be removed once we * get the cache device code in and take the * current AOR implementation out. */ #ifdef NEEDTOPORT if ((remote_sglist[i].addr >= (void *)vtophys(softc->mirr->addr)) && (remote_sglist[i].addr < ((void *)vtophys(softc->mirr->addr) + CacheMirrorOffset))) { local_sglist[i].addr = remote_sglist[i].addr - CacheMirrorOffset; if ((io->io_hdr.flags & CTL_FLAG_DATA_MASK) == CTL_FLAG_DATA_IN) io->io_hdr.flags |= CTL_FLAG_REDIR_DONE; } else { local_sglist[i].addr = remote_sglist[i].addr + CacheMirrorOffset; } #endif #if 0 printf("%s: local %p, remote %p, len %d\n", __func__, local_sglist[i].addr, remote_sglist[i].addr, local_sglist[i].len); #endif } } else { uint32_t len_to_go; /* * In this case, we don't have automatically allocated * memory for this I/O on this controller. This typically * happens with internal CTL I/O -- e.g. inquiry, mode * sense, etc. Anything coming from RAIDCore will have * a mirror area available. */ len_to_go = io->scsiio.kern_data_len; /* * Clear the no datasync flag, we have to use malloced * buffers. */ io->io_hdr.flags &= ~CTL_FLAG_NO_DATASYNC; /* * The difficult thing here is that the size of the various * S/G segments may be different than the size from the * remote controller. That'll make it harder when DMAing * the data back to the other side. */ for (i = 0; (i < sizeof(io->io_hdr.remote_sglist) / sizeof(io->io_hdr.remote_sglist[0])) && (len_to_go > 0); i++) { local_sglist[i].len = ctl_min(len_to_go, 131072); CTL_SIZE_8B(local_dma_sglist[i].len, local_sglist[i].len); local_sglist[i].addr = malloc(local_dma_sglist[i].len, M_CTL,M_WAITOK); local_dma_sglist[i].addr = local_sglist[i].addr; if (local_sglist[i].addr == NULL) { int j; printf("malloc failed for %zd bytes!", local_dma_sglist[i].len); for (j = 0; j < i; j++) { free(local_sglist[j].addr, M_CTL); } ctl_set_internal_failure(&io->scsiio, /*sks_valid*/ 1, /*retry_count*/ 4857); retval = 1; goto bailout_error; } /* XXX KDM do we need a sync here? */ len_to_go -= local_sglist[i].len; } /* * Reset the number of S/G entries accordingly. The * original number of S/G entries is available in * rem_sg_entries. */ io->scsiio.kern_sg_entries = i; #if 0 printf("%s: kern_sg_entries = %d\n", __func__, io->scsiio.kern_sg_entries); for (i = 0; i < io->scsiio.kern_sg_entries; i++) printf("%s: sg[%d] = %p, %d (DMA: %d)\n", __func__, i, local_sglist[i].addr, local_sglist[i].len, local_dma_sglist[i].len); #endif } return (retval); bailout_error: ctl_send_datamove_done(io, /*have_lock*/ 0); return (retval); } static int ctl_datamove_remote_xfer(union ctl_io *io, unsigned command, ctl_ha_dt_cb callback) { struct ctl_ha_dt_req *rq; struct ctl_sg_entry *remote_sglist, *local_sglist; struct ctl_sg_entry *remote_dma_sglist, *local_dma_sglist; uint32_t local_used, remote_used, total_used; int retval; int i, j; retval = 0; rq = ctl_dt_req_alloc(); /* * If we failed to allocate the request, and if the DMA didn't fail * anyway, set busy status. This is just a resource allocation * failure. */ if ((rq == NULL) && ((io->io_hdr.status & CTL_STATUS_MASK) != CTL_STATUS_NONE)) ctl_set_busy(&io->scsiio); if ((io->io_hdr.status & CTL_STATUS_MASK) != CTL_STATUS_NONE) { if (rq != NULL) ctl_dt_req_free(rq); /* * The data move failed. We need to return status back * to the other controller. No point in trying to DMA * data to the remote controller. */ ctl_send_datamove_done(io, /*have_lock*/ 0); retval = 1; goto bailout; } local_sglist = io->io_hdr.local_sglist; local_dma_sglist = io->io_hdr.local_dma_sglist; remote_sglist = io->io_hdr.remote_sglist; remote_dma_sglist = io->io_hdr.remote_dma_sglist; local_used = 0; remote_used = 0; total_used = 0; if (io->io_hdr.flags & CTL_FLAG_REDIR_DONE) { rq->ret = CTL_HA_STATUS_SUCCESS; rq->context = io; callback(rq); goto bailout; } /* * Pull/push the data over the wire from/to the other controller. * This takes into account the possibility that the local and * remote sglists may not be identical in terms of the size of * the elements and the number of elements. * * One fundamental assumption here is that the length allocated for * both the local and remote sglists is identical. Otherwise, we've * essentially got a coding error of some sort. */ for (i = 0, j = 0; total_used < io->scsiio.kern_data_len; ) { int isc_ret; uint32_t cur_len, dma_length; uint8_t *tmp_ptr; rq->id = CTL_HA_DATA_CTL; rq->command = command; rq->context = io; /* * Both pointers should be aligned. But it is possible * that the allocation length is not. They should both * also have enough slack left over at the end, though, * to round up to the next 8 byte boundary. */ cur_len = ctl_min(local_sglist[i].len - local_used, remote_sglist[j].len - remote_used); /* * In this case, we have a size issue and need to decrease * the size, except in the case where we actually have less * than 8 bytes left. In that case, we need to increase * the DMA length to get the last bit. */ if ((cur_len & 0x7) != 0) { if (cur_len > 0x7) { cur_len = cur_len - (cur_len & 0x7); dma_length = cur_len; } else { CTL_SIZE_8B(dma_length, cur_len); } } else dma_length = cur_len; /* * If we had to allocate memory for this I/O, instead of using * the non-cached mirror memory, we'll need to flush the cache * before trying to DMA to the other controller. * * We could end up doing this multiple times for the same * segment if we have a larger local segment than remote * segment. That shouldn't be an issue. */ if ((io->io_hdr.flags & CTL_FLAG_NO_DATASYNC) == 0) { /* * XXX KDM use bus_dmamap_sync() here. */ } rq->size = dma_length; tmp_ptr = (uint8_t *)local_sglist[i].addr; tmp_ptr += local_used; /* Use physical addresses when talking to ISC hardware */ if ((io->io_hdr.flags & CTL_FLAG_BUS_ADDR) == 0) { /* XXX KDM use busdma */ #if 0 rq->local = vtophys(tmp_ptr); #endif } else rq->local = tmp_ptr; tmp_ptr = (uint8_t *)remote_sglist[j].addr; tmp_ptr += remote_used; rq->remote = tmp_ptr; rq->callback = NULL; local_used += cur_len; if (local_used >= local_sglist[i].len) { i++; local_used = 0; } remote_used += cur_len; if (remote_used >= remote_sglist[j].len) { j++; remote_used = 0; } total_used += cur_len; if (total_used >= io->scsiio.kern_data_len) rq->callback = callback; if ((rq->size & 0x7) != 0) { printf("%s: warning: size %d is not on 8b boundary\n", __func__, rq->size); } if (((uintptr_t)rq->local & 0x7) != 0) { printf("%s: warning: local %p not on 8b boundary\n", __func__, rq->local); } if (((uintptr_t)rq->remote & 0x7) != 0) { printf("%s: warning: remote %p not on 8b boundary\n", __func__, rq->local); } #if 0 printf("%s: %s: local %#x remote %#x size %d\n", __func__, (command == CTL_HA_DT_CMD_WRITE) ? "WRITE" : "READ", rq->local, rq->remote, rq->size); #endif isc_ret = ctl_dt_single(rq); if (isc_ret == CTL_HA_STATUS_WAIT) continue; if (isc_ret == CTL_HA_STATUS_DISCONNECT) { rq->ret = CTL_HA_STATUS_SUCCESS; } else { rq->ret = isc_ret; } callback(rq); goto bailout; } bailout: return (retval); } static void ctl_datamove_remote_read(union ctl_io *io) { int retval; int i; /* * This will send an error to the other controller in the case of a * failure. */ retval = ctl_datamove_remote_sgl_setup(io); if (retval != 0) return; retval = ctl_datamove_remote_xfer(io, CTL_HA_DT_CMD_READ, ctl_datamove_remote_read_cb); if ((retval != 0) && ((io->io_hdr.flags & CTL_FLAG_AUTO_MIRROR) == 0)) { /* * Make sure we free memory if there was an error.. The * ctl_datamove_remote_xfer() function will send the * datamove done message, or call the callback with an * error if there is a problem. */ for (i = 0; i < io->scsiio.kern_sg_entries; i++) free(io->io_hdr.local_sglist[i].addr, M_CTL); } return; } /* * Process a datamove request from the other controller. This is used for * XFER mode only, not SER_ONLY mode. For writes, we DMA into local memory * first. Once that is complete, the data gets DMAed into the remote * controller's memory. For reads, we DMA from the remote controller's * memory into our memory first, and then move it out to the FETD. * * Should be called without the ctl_lock held. */ static void ctl_datamove_remote(union ctl_io *io) { struct ctl_softc *softc; softc = control_softc; /* * Note that we look for an aborted I/O here, but don't do some of * the other checks that ctl_datamove() normally does. We don't * need to run the task queue, because this I/O is on the ISC * queue, which is executed by the work thread after the task queue. * We don't need to run the datamove delay code, since that should * have been done if need be on the other controller. */ mtx_lock(&softc->ctl_lock); if (io->io_hdr.flags & CTL_FLAG_ABORT) { printf("%s: tag 0x%04x on (%d:%d:%d:%d) aborted\n", __func__, io->scsiio.tag_num, io->io_hdr.nexus.initid.id, io->io_hdr.nexus.targ_port, io->io_hdr.nexus.targ_target.id, io->io_hdr.nexus.targ_lun); io->io_hdr.status = CTL_CMD_ABORTED; io->io_hdr.port_status = 31338; mtx_unlock(&softc->ctl_lock); ctl_send_datamove_done(io, /*have_lock*/ 0); return; } if ((io->io_hdr.flags & CTL_FLAG_DATA_MASK) == CTL_FLAG_DATA_OUT) { mtx_unlock(&softc->ctl_lock); ctl_datamove_remote_write(io); } else if ((io->io_hdr.flags & CTL_FLAG_DATA_MASK) == CTL_FLAG_DATA_IN){ mtx_unlock(&softc->ctl_lock); ctl_datamove_remote_read(io); } else { union ctl_ha_msg msg; struct scsi_sense_data *sense; uint8_t sks[3]; int retry_count; memset(&msg, 0, sizeof(msg)); msg.hdr.msg_type = CTL_MSG_BAD_JUJU; msg.hdr.status = CTL_SCSI_ERROR; msg.scsi.scsi_status = SCSI_STATUS_CHECK_COND; retry_count = 4243; sense = &msg.scsi.sense_data; sks[0] = SSD_SCS_VALID; sks[1] = (retry_count >> 8) & 0xff; sks[2] = retry_count & 0xff; /* "Internal target failure" */ scsi_set_sense_data(sense, /*sense_format*/ SSD_TYPE_NONE, /*current_error*/ 1, /*sense_key*/ SSD_KEY_HARDWARE_ERROR, /*asc*/ 0x44, /*ascq*/ 0x00, /*type*/ SSD_ELEM_SKS, /*size*/ sizeof(sks), /*data*/ sks, SSD_ELEM_NONE); io->io_hdr.flags &= ~CTL_FLAG_IO_ACTIVE; if (io->io_hdr.flags & CTL_FLAG_FAILOVER) { ctl_failover_io(io, /*have_lock*/ 1); mtx_unlock(&softc->ctl_lock); return; } mtx_unlock(&softc->ctl_lock); if (ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg, sizeof(msg), 0) > CTL_HA_STATUS_SUCCESS) { /* XXX KDM what to do if this fails? */ } return; } } static int ctl_process_done(union ctl_io *io, int have_lock) { struct ctl_lun *lun; struct ctl_softc *ctl_softc; void (*fe_done)(union ctl_io *io); uint32_t targ_port = ctl_port_idx(io->io_hdr.nexus.targ_port); CTL_DEBUG_PRINT(("ctl_process_done\n")); fe_done = control_softc->ctl_ports[targ_port]->fe_done; #ifdef CTL_TIME_IO if ((time_uptime - io->io_hdr.start_time) > ctl_time_io_secs) { char str[256]; char path_str[64]; struct sbuf sb; ctl_scsi_path_string(io, path_str, sizeof(path_str)); sbuf_new(&sb, str, sizeof(str), SBUF_FIXEDLEN); sbuf_cat(&sb, path_str); switch (io->io_hdr.io_type) { case CTL_IO_SCSI: ctl_scsi_command_string(&io->scsiio, NULL, &sb); sbuf_printf(&sb, "\n"); sbuf_cat(&sb, path_str); sbuf_printf(&sb, "Tag: 0x%04x, type %d\n", io->scsiio.tag_num, io->scsiio.tag_type); break; case CTL_IO_TASK: sbuf_printf(&sb, "Task I/O type: %d, Tag: 0x%04x, " "Tag Type: %d\n", io->taskio.task_action, io->taskio.tag_num, io->taskio.tag_type); break; default: printf("Invalid CTL I/O type %d\n", io->io_hdr.io_type); panic("Invalid CTL I/O type %d\n", io->io_hdr.io_type); break; } sbuf_cat(&sb, path_str); sbuf_printf(&sb, "ctl_process_done: %jd seconds\n", (intmax_t)time_uptime - io->io_hdr.start_time); sbuf_finish(&sb); printf("%s", sbuf_data(&sb)); } #endif /* CTL_TIME_IO */ switch (io->io_hdr.io_type) { case CTL_IO_SCSI: break; case CTL_IO_TASK: ctl_io_error_print(io, NULL); if (io->io_hdr.flags & CTL_FLAG_FROM_OTHER_SC) ctl_free_io_internal(io, /*have_lock*/ 0); else fe_done(io); return (CTL_RETVAL_COMPLETE); break; default: printf("ctl_process_done: invalid io type %d\n", io->io_hdr.io_type); panic("ctl_process_done: invalid io type %d\n", io->io_hdr.io_type); break; /* NOTREACHED */ } lun = (struct ctl_lun *)io->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; if (lun == NULL) { CTL_DEBUG_PRINT(("NULL LUN for lun %d\n", io->io_hdr.nexus.targ_lun)); fe_done(io); goto bailout; } ctl_softc = lun->ctl_softc; /* * Remove this from the OOA queue. */ if (have_lock == 0) mtx_lock(&ctl_softc->ctl_lock); /* * Check to see if we have any errors to inject here. We only * inject errors for commands that don't already have errors set. */ if ((STAILQ_FIRST(&lun->error_list) != NULL) && ((io->io_hdr.status & CTL_STATUS_MASK) == CTL_SUCCESS)) ctl_inject_error(lun, io); /* * XXX KDM how do we treat commands that aren't completed * successfully? * * XXX KDM should we also track I/O latency? */ if ((io->io_hdr.status & CTL_STATUS_MASK) == CTL_SUCCESS) { uint32_t blocksize; #ifdef CTL_TIME_IO struct bintime cur_bt; #endif if ((lun->be_lun != NULL) && (lun->be_lun->blocksize != 0)) blocksize = lun->be_lun->blocksize; else blocksize = 512; switch (io->io_hdr.io_type) { case CTL_IO_SCSI: { int isread; struct ctl_lba_len lbalen; isread = 0; switch (io->scsiio.cdb[0]) { case READ_6: case READ_10: case READ_12: case READ_16: isread = 1; /* FALLTHROUGH */ case WRITE_6: case WRITE_10: case WRITE_12: case WRITE_16: case WRITE_VERIFY_10: case WRITE_VERIFY_12: case WRITE_VERIFY_16: memcpy(&lbalen, io->io_hdr.ctl_private[ CTL_PRIV_LBA_LEN].bytes, sizeof(lbalen)); if (isread) { lun->stats.ports[targ_port].bytes[CTL_STATS_READ] += lbalen.len * blocksize; lun->stats.ports[targ_port].operations[CTL_STATS_READ]++; #ifdef CTL_TIME_IO bintime_add( &lun->stats.ports[targ_port].dma_time[CTL_STATS_READ], &io->io_hdr.dma_bt); lun->stats.ports[targ_port].num_dmas[CTL_STATS_READ] += io->io_hdr.num_dmas; getbintime(&cur_bt); bintime_sub(&cur_bt, &io->io_hdr.start_bt); bintime_add( &lun->stats.ports[targ_port].time[CTL_STATS_READ], &cur_bt); #if 0 cs_prof_gettime(&cur_ticks); lun->stats.time[CTL_STATS_READ] += cur_ticks - io->io_hdr.start_ticks; #endif #if 0 lun->stats.time[CTL_STATS_READ] += jiffies - io->io_hdr.start_time; #endif #endif /* CTL_TIME_IO */ } else { lun->stats.ports[targ_port].bytes[CTL_STATS_WRITE] += lbalen.len * blocksize; lun->stats.ports[targ_port].operations[ CTL_STATS_WRITE]++; #ifdef CTL_TIME_IO bintime_add( &lun->stats.ports[targ_port].dma_time[CTL_STATS_WRITE], &io->io_hdr.dma_bt); lun->stats.ports[targ_port].num_dmas[CTL_STATS_WRITE] += io->io_hdr.num_dmas; getbintime(&cur_bt); bintime_sub(&cur_bt, &io->io_hdr.start_bt); bintime_add( &lun->stats.ports[targ_port].time[CTL_STATS_WRITE], &cur_bt); #if 0 cs_prof_gettime(&cur_ticks); lun->stats.ports[targ_port].time[CTL_STATS_WRITE] += cur_ticks - io->io_hdr.start_ticks; lun->stats.ports[targ_port].time[CTL_STATS_WRITE] += jiffies - io->io_hdr.start_time; #endif #endif /* CTL_TIME_IO */ } break; default: lun->stats.ports[targ_port].operations[CTL_STATS_NO_IO]++; #ifdef CTL_TIME_IO bintime_add( &lun->stats.ports[targ_port].dma_time[CTL_STATS_NO_IO], &io->io_hdr.dma_bt); lun->stats.ports[targ_port].num_dmas[CTL_STATS_NO_IO] += io->io_hdr.num_dmas; getbintime(&cur_bt); bintime_sub(&cur_bt, &io->io_hdr.start_bt); bintime_add(&lun->stats.ports[targ_port].time[CTL_STATS_NO_IO], &cur_bt); #if 0 cs_prof_gettime(&cur_ticks); lun->stats.ports[targ_port].time[CTL_STATS_NO_IO] += cur_ticks - io->io_hdr.start_ticks; lun->stats.ports[targ_port].time[CTL_STATS_NO_IO] += jiffies - io->io_hdr.start_time; #endif #endif /* CTL_TIME_IO */ break; } break; } default: break; } } TAILQ_REMOVE(&lun->ooa_queue, &io->io_hdr, ooa_links); /* * Run through the blocked queue on this LUN and see if anything * has become unblocked, now that this transaction is done. */ ctl_check_blocked(lun); /* * If the LUN has been invalidated, free it if there is nothing * left on its OOA queue. */ if ((lun->flags & CTL_LUN_INVALID) && (TAILQ_FIRST(&lun->ooa_queue) == NULL)) ctl_free_lun(lun); /* * If this command has been aborted, make sure we set the status * properly. The FETD is responsible for freeing the I/O and doing * whatever it needs to do to clean up its state. */ if (io->io_hdr.flags & CTL_FLAG_ABORT) io->io_hdr.status = CTL_CMD_ABORTED; /* * We print out status for every task management command. For SCSI * commands, we filter out any unit attention errors; they happen * on every boot, and would clutter up the log. Note: task * management commands aren't printed here, they are printed above, * since they should never even make it down here. */ switch (io->io_hdr.io_type) { case CTL_IO_SCSI: { int error_code, sense_key, asc, ascq; sense_key = 0; if (((io->io_hdr.status & CTL_STATUS_MASK) == CTL_SCSI_ERROR) && (io->scsiio.scsi_status == SCSI_STATUS_CHECK_COND)) { /* * Since this is just for printing, no need to * show errors here. */ scsi_extract_sense_len(&io->scsiio.sense_data, io->scsiio.sense_len, &error_code, &sense_key, &asc, &ascq, /*show_errors*/ 0); } if (((io->io_hdr.status & CTL_STATUS_MASK) != CTL_SUCCESS) && (((io->io_hdr.status & CTL_STATUS_MASK) != CTL_SCSI_ERROR) || (io->scsiio.scsi_status != SCSI_STATUS_CHECK_COND) || (sense_key != SSD_KEY_UNIT_ATTENTION))) { if ((time_uptime - ctl_softc->last_print_jiffies) <= 0){ ctl_softc->skipped_prints++; if (have_lock == 0) mtx_unlock(&ctl_softc->ctl_lock); } else { uint32_t skipped_prints; skipped_prints = ctl_softc->skipped_prints; ctl_softc->skipped_prints = 0; ctl_softc->last_print_jiffies = time_uptime; if (have_lock == 0) mtx_unlock(&ctl_softc->ctl_lock); if (skipped_prints > 0) { #ifdef NEEDTOPORT csevent_log(CSC_CTL | CSC_SHELF_SW | CTL_ERROR_REPORT, csevent_LogType_Trace, csevent_Severity_Information, csevent_AlertLevel_Green, csevent_FRU_Firmware, csevent_FRU_Unknown, "High CTL error volume, %d prints " "skipped", skipped_prints); #endif } ctl_io_error_print(io, NULL); } } else { if (have_lock == 0) mtx_unlock(&ctl_softc->ctl_lock); } break; } case CTL_IO_TASK: if (have_lock == 0) mtx_unlock(&ctl_softc->ctl_lock); ctl_io_error_print(io, NULL); break; default: if (have_lock == 0) mtx_unlock(&ctl_softc->ctl_lock); break; } /* * Tell the FETD or the other shelf controller we're done with this * command. Note that only SCSI commands get to this point. Task * management commands are completed above. * * We only send status to the other controller if we're in XFER * mode. In SER_ONLY mode, the I/O is done on the controller that * received the I/O (from CTL's perspective), and so the status is * generated there. * * XXX KDM if we hold the lock here, we could cause a deadlock * if the frontend comes back in in this context to queue * something. */ if ((ctl_softc->ha_mode == CTL_HA_MODE_XFER) && (io->io_hdr.flags & CTL_FLAG_FROM_OTHER_SC)) { union ctl_ha_msg msg; memset(&msg, 0, sizeof(msg)); msg.hdr.msg_type = CTL_MSG_FINISH_IO; msg.hdr.original_sc = io->io_hdr.original_sc; msg.hdr.nexus = io->io_hdr.nexus; msg.hdr.status = io->io_hdr.status; msg.scsi.scsi_status = io->scsiio.scsi_status; msg.scsi.tag_num = io->scsiio.tag_num; msg.scsi.tag_type = io->scsiio.tag_type; msg.scsi.sense_len = io->scsiio.sense_len; msg.scsi.sense_residual = io->scsiio.sense_residual; msg.scsi.residual = io->scsiio.residual; memcpy(&msg.scsi.sense_data, &io->scsiio.sense_data, sizeof(io->scsiio.sense_data)); /* * We copy this whether or not this is an I/O-related * command. Otherwise, we'd have to go and check to see * whether it's a read/write command, and it really isn't * worth it. */ memcpy(&msg.scsi.lbalen, &io->io_hdr.ctl_private[CTL_PRIV_LBA_LEN].bytes, sizeof(msg.scsi.lbalen));; if (ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg, sizeof(msg), 0) > CTL_HA_STATUS_SUCCESS) { /* XXX do something here */ } ctl_free_io_internal(io, /*have_lock*/ 0); } else fe_done(io); bailout: return (CTL_RETVAL_COMPLETE); } /* * Front end should call this if it doesn't do autosense. When the request * sense comes back in from the initiator, we'll dequeue this and send it. */ int ctl_queue_sense(union ctl_io *io) { struct ctl_lun *lun; struct ctl_softc *ctl_softc; uint32_t initidx; ctl_softc = control_softc; CTL_DEBUG_PRINT(("ctl_queue_sense\n")); /* * LUN lookup will likely move to the ctl_work_thread() once we * have our new queueing infrastructure (that doesn't put things on * a per-LUN queue initially). That is so that we can handle * things like an INQUIRY to a LUN that we don't have enabled. We * can't deal with that right now. */ mtx_lock(&ctl_softc->ctl_lock); /* * If we don't have a LUN for this, just toss the sense * information. */ if ((io->io_hdr.nexus.targ_lun < CTL_MAX_LUNS) && (ctl_softc->ctl_luns[io->io_hdr.nexus.targ_lun] != NULL)) lun = ctl_softc->ctl_luns[io->io_hdr.nexus.targ_lun]; else goto bailout; initidx = ctl_get_initindex(&io->io_hdr.nexus); /* * Already have CA set for this LUN...toss the sense information. */ if (ctl_is_set(lun->have_ca, initidx)) goto bailout; memcpy(&lun->pending_sense[initidx].sense, &io->scsiio.sense_data, ctl_min(sizeof(lun->pending_sense[initidx].sense), sizeof(io->scsiio.sense_data))); ctl_set_mask(lun->have_ca, initidx); bailout: mtx_unlock(&ctl_softc->ctl_lock); ctl_free_io(io); return (CTL_RETVAL_COMPLETE); } /* * Primary command inlet from frontend ports. All SCSI and task I/O * requests must go through this function. */ int ctl_queue(union ctl_io *io) { struct ctl_softc *ctl_softc; CTL_DEBUG_PRINT(("ctl_queue cdb[0]=%02X\n", io->scsiio.cdb[0])); ctl_softc = control_softc; #ifdef CTL_TIME_IO io->io_hdr.start_time = time_uptime; getbintime(&io->io_hdr.start_bt); #endif /* CTL_TIME_IO */ mtx_lock(&ctl_softc->ctl_lock); switch (io->io_hdr.io_type) { case CTL_IO_SCSI: STAILQ_INSERT_TAIL(&ctl_softc->incoming_queue, &io->io_hdr, links); break; case CTL_IO_TASK: STAILQ_INSERT_TAIL(&ctl_softc->task_queue, &io->io_hdr, links); /* * Set the task pending flag. This is necessary to close a * race condition with the FETD: * * - FETD submits a task management command, like an abort. * - Back end calls fe_datamove() to move the data for the * aborted command. The FETD can't really accept it, but * if it did, it would end up transmitting data for a * command that the initiator told us to abort. * * We close the race condition by setting the flag here, * and checking it in ctl_datamove(), before calling the * FETD's fe_datamove routine. If we've got a task * pending, we run the task queue and then check to see * whether our particular I/O has been aborted. */ ctl_softc->flags |= CTL_FLAG_TASK_PENDING; break; default: mtx_unlock(&ctl_softc->ctl_lock); printf("ctl_queue: unknown I/O type %d\n", io->io_hdr.io_type); return (-EINVAL); break; /* NOTREACHED */ } mtx_unlock(&ctl_softc->ctl_lock); ctl_wakeup_thread(); return (CTL_RETVAL_COMPLETE); } #ifdef CTL_IO_DELAY static void ctl_done_timer_wakeup(void *arg) { union ctl_io *io; io = (union ctl_io *)arg; ctl_done_lock(io, /*have_lock*/ 0); } #endif /* CTL_IO_DELAY */ void ctl_done_lock(union ctl_io *io, int have_lock) { struct ctl_softc *ctl_softc; #ifndef CTL_DONE_THREAD union ctl_io *xio; #endif /* !CTL_DONE_THREAD */ ctl_softc = control_softc; if (have_lock == 0) mtx_lock(&ctl_softc->ctl_lock); /* * Enable this to catch duplicate completion issues. */ #if 0 if (io->io_hdr.flags & CTL_FLAG_ALREADY_DONE) { printf("%s: type %d msg %d cdb %x iptl: " "%d:%d:%d:%d tag 0x%04x " "flag %#x status %x\n", __func__, io->io_hdr.io_type, io->io_hdr.msg_type, io->scsiio.cdb[0], io->io_hdr.nexus.initid.id, io->io_hdr.nexus.targ_port, io->io_hdr.nexus.targ_target.id, io->io_hdr.nexus.targ_lun, (io->io_hdr.io_type == CTL_IO_TASK) ? io->taskio.tag_num : io->scsiio.tag_num, io->io_hdr.flags, io->io_hdr.status); } else io->io_hdr.flags |= CTL_FLAG_ALREADY_DONE; #endif /* * This is an internal copy of an I/O, and should not go through * the normal done processing logic. */ if (io->io_hdr.flags & CTL_FLAG_INT_COPY) { if (have_lock == 0) mtx_unlock(&ctl_softc->ctl_lock); return; } /* * We need to send a msg to the serializing shelf to finish the IO * as well. We don't send a finish message to the other shelf if * this is a task management command. Task management commands * aren't serialized in the OOA queue, but rather just executed on * both shelf controllers for commands that originated on that * controller. */ if ((io->io_hdr.flags & CTL_FLAG_SENT_2OTHER_SC) && (io->io_hdr.io_type != CTL_IO_TASK)) { union ctl_ha_msg msg_io; msg_io.hdr.msg_type = CTL_MSG_FINISH_IO; msg_io.hdr.serializing_sc = io->io_hdr.serializing_sc; if (ctl_ha_msg_send(CTL_HA_CHAN_CTL, &msg_io, sizeof(msg_io), 0 ) != CTL_HA_STATUS_SUCCESS) { } /* continue on to finish IO */ } #ifdef CTL_IO_DELAY if (io->io_hdr.flags & CTL_FLAG_DELAY_DONE) { struct ctl_lun *lun; lun =(struct ctl_lun *)io->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; io->io_hdr.flags &= ~CTL_FLAG_DELAY_DONE; } else { struct ctl_lun *lun; lun =(struct ctl_lun *)io->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; if ((lun != NULL) && (lun->delay_info.done_delay > 0)) { struct callout *callout; callout = (struct callout *)&io->io_hdr.timer_bytes; callout_init(callout, /*mpsafe*/ 1); io->io_hdr.flags |= CTL_FLAG_DELAY_DONE; callout_reset(callout, lun->delay_info.done_delay * hz, ctl_done_timer_wakeup, io); if (lun->delay_info.done_type == CTL_DELAY_TYPE_ONESHOT) lun->delay_info.done_delay = 0; if (have_lock == 0) mtx_unlock(&ctl_softc->ctl_lock); return; } } #endif /* CTL_IO_DELAY */ STAILQ_INSERT_TAIL(&ctl_softc->done_queue, &io->io_hdr, links); #ifdef CTL_DONE_THREAD if (have_lock == 0) mtx_unlock(&ctl_softc->ctl_lock); ctl_wakeup_thread(); #else /* CTL_DONE_THREAD */ for (xio = (union ctl_io *)STAILQ_FIRST(&ctl_softc->done_queue); xio != NULL; xio =(union ctl_io *)STAILQ_FIRST(&ctl_softc->done_queue)) { STAILQ_REMOVE_HEAD(&ctl_softc->done_queue, links); ctl_process_done(xio, /*have_lock*/ 1); } if (have_lock == 0) mtx_unlock(&ctl_softc->ctl_lock); #endif /* CTL_DONE_THREAD */ } void ctl_done(union ctl_io *io) { ctl_done_lock(io, /*have_lock*/ 0); } int ctl_isc(struct ctl_scsiio *ctsio) { struct ctl_lun *lun; int retval; lun = (struct ctl_lun *)ctsio->io_hdr.ctl_private[CTL_PRIV_LUN].ptr; CTL_DEBUG_PRINT(("ctl_isc: command: %02x\n", ctsio->cdb[0])); CTL_DEBUG_PRINT(("ctl_isc: calling data_submit()\n")); retval = lun->backend->data_submit((union ctl_io *)ctsio); return (retval); } static void ctl_work_thread(void *arg) { struct ctl_softc *softc; union ctl_io *io; struct ctl_be_lun *be_lun; int retval; CTL_DEBUG_PRINT(("ctl_work_thread starting\n")); softc = (struct ctl_softc *)arg; if (softc == NULL) return; mtx_lock(&softc->ctl_lock); for (;;) { retval = 0; /* * We handle the queues in this order: * - task management * - ISC * - done queue (to free up resources, unblock other commands) * - RtR queue * - incoming queue * * If those queues are empty, we break out of the loop and * go to sleep. */ io = (union ctl_io *)STAILQ_FIRST(&softc->task_queue); if (io != NULL) { ctl_run_task_queue(softc); continue; } io = (union ctl_io *)STAILQ_FIRST(&softc->isc_queue); if (io != NULL) { STAILQ_REMOVE_HEAD(&softc->isc_queue, links); ctl_handle_isc(io); continue; } io = (union ctl_io *)STAILQ_FIRST(&softc->done_queue); if (io != NULL) { STAILQ_REMOVE_HEAD(&softc->done_queue, links); /* clear any blocked commands, call fe_done */ mtx_unlock(&softc->ctl_lock); /* * XXX KDM * Call this without a lock for now. This will * depend on whether there is any way the FETD can * sleep or deadlock if called with the CTL lock * held. */ retval = ctl_process_done(io, /*have_lock*/ 0); mtx_lock(&softc->ctl_lock); continue; } if (!ctl_pause_rtr) { io = (union ctl_io *)STAILQ_FIRST(&softc->rtr_queue); if (io != NULL) { STAILQ_REMOVE_HEAD(&softc->rtr_queue, links); mtx_unlock(&softc->ctl_lock); goto execute; } } io = (union ctl_io *)STAILQ_FIRST(&softc->incoming_queue); if (io != NULL) { STAILQ_REMOVE_HEAD(&softc->incoming_queue, links); mtx_unlock(&softc->ctl_lock); ctl_scsiio_precheck(softc, &io->scsiio); mtx_lock(&softc->ctl_lock); continue; } /* * We might want to move this to a separate thread, so that * configuration requests (in this case LUN creations) * won't impact the I/O path. */ be_lun = STAILQ_FIRST(&softc->pending_lun_queue); if (be_lun != NULL) { STAILQ_REMOVE_HEAD(&softc->pending_lun_queue, links); mtx_unlock(&softc->ctl_lock); ctl_create_lun(be_lun); mtx_lock(&softc->ctl_lock); continue; } /* XXX KDM use the PDROP flag?? */ /* Sleep until we have something to do. */ mtx_sleep(softc, &softc->ctl_lock, PRIBIO, "ctl_work", 0); /* Back to the top of the loop to see what woke us up. */ continue; execute: retval = ctl_scsiio(&io->scsiio); switch (retval) { case CTL_RETVAL_COMPLETE: break; default: /* * Probably need to make sure this doesn't happen. */ break; } mtx_lock(&softc->ctl_lock); } } void ctl_wakeup_thread() { struct ctl_softc *softc; softc = control_softc; wakeup(softc); } /* Initialization and failover */ void ctl_init_isc_msg(void) { printf("CTL: Still calling this thing\n"); } /* * Init component * Initializes component into configuration defined by bootMode * (see hasc-sv.c) * returns hasc_Status: * OK * ERROR - fatal error */ static ctl_ha_comp_status ctl_isc_init(struct ctl_ha_component *c) { ctl_ha_comp_status ret = CTL_HA_COMP_STATUS_OK; c->status = ret; return ret; } /* Start component * Starts component in state requested. If component starts successfully, * it must set its own state to the requestrd state * When requested state is HASC_STATE_HA, the component may refine it * by adding _SLAVE or _MASTER flags. * Currently allowed state transitions are: * UNKNOWN->HA - initial startup * UNKNOWN->SINGLE - initial startup when no parter detected * HA->SINGLE - failover * returns ctl_ha_comp_status: * OK - component successfully started in requested state * FAILED - could not start the requested state, failover may * be possible * ERROR - fatal error detected, no future startup possible */ static ctl_ha_comp_status ctl_isc_start(struct ctl_ha_component *c, ctl_ha_state state) { ctl_ha_comp_status ret = CTL_HA_COMP_STATUS_OK; // UNKNOWN->HA or UNKNOWN->SINGLE (bootstrap) if (c->state == CTL_HA_STATE_UNKNOWN ) { ctl_is_single = 0; if (ctl_ha_msg_create(CTL_HA_CHAN_CTL, ctl_isc_event_handler) != CTL_HA_STATUS_SUCCESS) { printf("ctl_isc_start: ctl_ha_msg_create failed.\n"); ret = CTL_HA_COMP_STATUS_ERROR; } } else if (CTL_HA_STATE_IS_HA(c->state) && CTL_HA_STATE_IS_SINGLE(state)){ // HA->SINGLE transition ctl_failover(); ctl_is_single = 1; } else { printf("ctl_isc_start:Invalid state transition %X->%X\n", c->state, state); ret = CTL_HA_COMP_STATUS_ERROR; } if (CTL_HA_STATE_IS_SINGLE(state)) ctl_is_single = 1; c->state = state; c->status = ret; return ret; } /* * Quiesce component * The component must clear any error conditions (set status to OK) and * prepare itself to another Start call * returns ctl_ha_comp_status: * OK * ERROR */ static ctl_ha_comp_status ctl_isc_quiesce(struct ctl_ha_component *c) { int ret = CTL_HA_COMP_STATUS_OK; ctl_pause_rtr = 1; c->status = ret; return ret; } struct ctl_ha_component ctl_ha_component_ctlisc = { .name = "CTL ISC", .state = CTL_HA_STATE_UNKNOWN, .init = ctl_isc_init, .start = ctl_isc_start, .quiesce = ctl_isc_quiesce }; /* * vim: ts=8 */