/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2006 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * SATA Framework * Generic SATA Host Adapter Implementation * * NOTE: THIS VERSION DOES NOT SUPPORT ATAPI DEVICES, * although there is some code related to these devices. * */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* Debug flags - defined in sata.h */ int sata_debug_flags = 0; /* * Flags enabling selected SATA HBA framework functionality */ #define SATA_ENABLE_QUEUING 1 #define SATA_ENABLE_NCQ 2 #define SATA_ENABLE_PROCESS_EVENTS 4 static int sata_func_enable = SATA_ENABLE_PROCESS_EVENTS; #ifdef SATA_DEBUG #define SATA_LOG_D(args) sata_log args #else #define SATA_LOG_D(arg) #endif /* * SATA cb_ops functions */ static int sata_hba_open(dev_t *, int, int, cred_t *); static int sata_hba_close(dev_t, int, int, cred_t *); static int sata_hba_ioctl(dev_t, int, intptr_t, int, cred_t *, int *); /* * SCSA required entry points */ static int sata_scsi_tgt_init(dev_info_t *, dev_info_t *, scsi_hba_tran_t *, struct scsi_device *); static int sata_scsi_tgt_probe(struct scsi_device *, int (*callback)(void)); static void sata_scsi_tgt_free(dev_info_t *, dev_info_t *, scsi_hba_tran_t *, struct scsi_device *); static int sata_scsi_start(struct scsi_address *, struct scsi_pkt *); static int sata_scsi_abort(struct scsi_address *, struct scsi_pkt *); static int sata_scsi_reset(struct scsi_address *, int); static int sata_scsi_getcap(struct scsi_address *, char *, int); static int sata_scsi_setcap(struct scsi_address *, char *, int, int); static struct scsi_pkt *sata_scsi_init_pkt(struct scsi_address *, struct scsi_pkt *, struct buf *, int, int, int, int, int (*)(caddr_t), caddr_t); static void sata_scsi_destroy_pkt(struct scsi_address *, struct scsi_pkt *); static void sata_scsi_dmafree(struct scsi_address *, struct scsi_pkt *); static void sata_scsi_sync_pkt(struct scsi_address *, struct scsi_pkt *); static int sata_scsi_get_name(struct scsi_device *, char *, int); /* * Local functions */ static void sata_remove_hba_instance(dev_info_t *); static int sata_validate_sata_hba_tran(dev_info_t *, sata_hba_tran_t *); static void sata_probe_ports(sata_hba_inst_t *); static int sata_reprobe_port(sata_hba_inst_t *, sata_device_t *); static void sata_make_device_nodes(dev_info_t *, sata_hba_inst_t *); static dev_info_t *sata_create_target_node(dev_info_t *, sata_hba_inst_t *, sata_address_t *); static int sata_validate_scsi_address(sata_hba_inst_t *, struct scsi_address *, sata_device_t *); static int sata_validate_sata_address(sata_hba_inst_t *, int, int, int); static sata_pkt_t *sata_pkt_alloc(sata_pkt_txlate_t *, int (*)(caddr_t)); static void sata_pkt_free(sata_pkt_txlate_t *); static int sata_dma_buf_setup(sata_pkt_txlate_t *, int, int (*)(caddr_t), caddr_t, ddi_dma_attr_t *); static int sata_probe_device(sata_hba_inst_t *, sata_device_t *); static sata_drive_info_t *sata_get_device_info(sata_hba_inst_t *, sata_device_t *); static int sata_identify_device(sata_hba_inst_t *, sata_drive_info_t *); static struct buf *sata_alloc_local_buffer(sata_pkt_txlate_t *, int); static void sata_free_local_buffer(sata_pkt_txlate_t *); static uint64_t sata_check_capacity(sata_drive_info_t *); void sata_adjust_dma_attr(sata_drive_info_t *, ddi_dma_attr_t *, ddi_dma_attr_t *); static int sata_fetch_device_identify_data(sata_hba_inst_t *, sata_drive_info_t *); static void sata_update_port_info(sata_hba_inst_t *, sata_device_t *); static void sata_update_port_scr(sata_port_scr_t *, sata_device_t *); static int sata_set_udma_mode(sata_hba_inst_t *, sata_drive_info_t *); /* Event processing functions */ static void sata_event_daemon(void *); static void sata_event_thread_control(int); static void sata_process_controller_events(sata_hba_inst_t *sata_hba_inst); static void sata_process_device_reset(sata_hba_inst_t *, sata_address_t *); static void sata_process_port_failed_event(sata_hba_inst_t *, sata_address_t *); static void sata_process_port_link_events(sata_hba_inst_t *, sata_address_t *); static void sata_process_device_detached(sata_hba_inst_t *, sata_address_t *); static void sata_process_device_attached(sata_hba_inst_t *, sata_address_t *); static void sata_process_port_pwr_change(sata_hba_inst_t *, sata_address_t *); static void sata_process_cntrl_pwr_level_change(sata_hba_inst_t *); static int sata_restore_drive_settings(sata_hba_inst_t *, sata_drive_info_t *); /* Local functions for ioctl */ static int32_t sata_get_port_num(sata_hba_inst_t *, struct devctl_iocdata *); static void sata_cfgadm_state(sata_hba_inst_t *, int32_t, devctl_ap_state_t *); static dev_info_t *sata_get_target_dip(dev_info_t *, int32_t); static dev_info_t *sata_devt_to_devinfo(dev_t); /* Local translation functions */ static int sata_txlt_inquiry(sata_pkt_txlate_t *); static int sata_txlt_test_unit_ready(sata_pkt_txlate_t *); static int sata_txlt_start_stop_unit(sata_pkt_txlate_t *); static int sata_txlt_read_capacity(sata_pkt_txlate_t *); static int sata_txlt_request_sense(sata_pkt_txlate_t *); static int sata_txlt_read(sata_pkt_txlate_t *); static int sata_txlt_write(sata_pkt_txlate_t *); static int sata_txlt_atapi(sata_pkt_txlate_t *); static int sata_txlt_log_sense(sata_pkt_txlate_t *); static int sata_txlt_log_select(sata_pkt_txlate_t *); static int sata_txlt_mode_sense(sata_pkt_txlate_t *); static int sata_txlt_mode_select(sata_pkt_txlate_t *); static int sata_txlt_synchronize_cache(sata_pkt_txlate_t *); static int sata_txlt_nodata_cmd_immediate(sata_pkt_txlate_t *); static int sata_hba_start(sata_pkt_txlate_t *, int *); static int sata_txlt_invalid_command(sata_pkt_txlate_t *); static int sata_txlt_lba_out_of_range(sata_pkt_txlate_t *); static void sata_txlt_rw_completion(sata_pkt_t *); static void sata_txlt_atapi_completion(sata_pkt_t *); static void sata_txlt_nodata_cmd_completion(sata_pkt_t *); static struct scsi_extended_sense *sata_immediate_error_response( sata_pkt_txlate_t *, int); static struct scsi_extended_sense *sata_arq_sense(sata_pkt_txlate_t *); /* Local functions */ static void sata_identdev_to_inquiry(sata_hba_inst_t *, sata_drive_info_t *, uint8_t *); static int sata_build_msense_page_1(sata_drive_info_t *, int, uint8_t *); static int sata_build_msense_page_8(sata_drive_info_t *, int, uint8_t *); static int sata_build_msense_page_1a(sata_drive_info_t *, int, uint8_t *); static int sata_build_msense_page_1c(sata_drive_info_t *, int, uint8_t *); static int sata_mode_select_page_8(sata_pkt_txlate_t *, struct mode_cache_scsi3 *, int, int *, int *, int *); static int sata_mode_select_page_1c(sata_pkt_txlate_t *, struct mode_info_excpt_page *, int, int *, int *, int *); static int sata_build_lsense_page_0(sata_drive_info_t *, uint8_t *); static int sata_build_lsense_page_10(sata_drive_info_t *, uint8_t *, sata_hba_inst_t *); static int sata_build_lsense_page_2f(sata_drive_info_t *, uint8_t *, sata_hba_inst_t *); static int sata_build_lsense_page_30(sata_drive_info_t *, uint8_t *, sata_hba_inst_t *); static void sata_save_drive_settings(sata_drive_info_t *); static void sata_show_drive_info(sata_hba_inst_t *, sata_drive_info_t *); static void sata_log(sata_hba_inst_t *, uint_t, char *fmt, ...); static int sata_fetch_smart_return_status(sata_hba_inst_t *, sata_drive_info_t *); static int sata_fetch_smart_data(sata_hba_inst_t *, sata_drive_info_t *, struct smart_data *); static int sata_smart_selftest_log(sata_hba_inst_t *, sata_drive_info_t *, struct smart_selftest_log *); static int sata_ext_smart_selftest_read_log(sata_hba_inst_t *, sata_drive_info_t *, struct smart_ext_selftest_log *, uint16_t); static int sata_smart_read_log(sata_hba_inst_t *, sata_drive_info_t *, uint8_t *, uint8_t, uint8_t); static int sata_read_log_ext_directory(sata_hba_inst_t *, sata_drive_info_t *, struct read_log_ext_directory *); static void sata_gen_sysevent(sata_hba_inst_t *, sata_address_t *, int); static void sata_xlate_errors(sata_pkt_txlate_t *); /* * SATA Framework will ignore SATA HBA driver cb_ops structure and * register following one with SCSA framework. * Open & close are provided, so scsi framework will not use its own */ static struct cb_ops sata_cb_ops = { sata_hba_open, /* open */ sata_hba_close, /* close */ nodev, /* strategy */ nodev, /* print */ nodev, /* dump */ nodev, /* read */ nodev, /* write */ sata_hba_ioctl, /* ioctl */ nodev, /* devmap */ nodev, /* mmap */ nodev, /* segmap */ nochpoll, /* chpoll */ ddi_prop_op, /* cb_prop_op */ 0, /* streamtab */ D_NEW | D_MP, /* cb_flag */ CB_REV, /* rev */ nodev, /* aread */ nodev /* awrite */ }; extern struct mod_ops mod_miscops; extern uchar_t scsi_cdb_size[]; static struct modlmisc modlmisc = { &mod_miscops, /* Type of module */ "Generic SATA Driver v%I%" /* module name */ }; static struct modlinkage modlinkage = { MODREV_1, (void *)&modlmisc, NULL }; /* * Default sata pkt timeout. Used when a target driver scsi_pkt time is zero, * i.e. when scsi_pkt has not timeout specified. */ static int sata_default_pkt_time = 60; /* 60 seconds */ /* * Mutexes protecting structures in multithreaded operations. * Because events are relatively rare, a single global mutex protecting * data structures should be sufficient. To increase performance, add * separate mutex per each sata port and use global mutex only to protect * common data structures. */ static kmutex_t sata_mutex; /* protects sata_hba_list */ static kmutex_t sata_log_mutex; /* protects log */ static char sata_log_buf[256]; /* * Linked list of HBA instances */ static sata_hba_inst_t *sata_hba_list = NULL; static sata_hba_inst_t *sata_hba_list_tail = NULL; /* * Pointer to per-instance SATA HBA soft structure is stored in sata_hba_tran * structure and in sata soft state. */ /* * Event daemon related variables */ static kmutex_t sata_event_mutex; static kcondvar_t sata_event_cv; static kthread_t *sata_event_thread = NULL; static int sata_event_thread_terminate = 0; static int sata_event_pending = 0; static int sata_event_thread_active = 0; extern pri_t minclsyspri; /* Warlock directives */ _NOTE(SCHEME_PROTECTS_DATA("No Mutex Needed", scsi_hba_tran)) _NOTE(SCHEME_PROTECTS_DATA("No Mutex Needed", scsi_device)) _NOTE(SCHEME_PROTECTS_DATA("No Mutex Needed", dev_ops)) _NOTE(SCHEME_PROTECTS_DATA("No Mutex Needed", scsi_extended_sense)) _NOTE(SCHEME_PROTECTS_DATA("No Mutex Needed", scsi_arq_status)) _NOTE(SCHEME_PROTECTS_DATA("No Mutex Needed", ddi_dma_attr)) _NOTE(SCHEME_PROTECTS_DATA("No Mutex Needed", ddi_dma_cookie_t)) _NOTE(SCHEME_PROTECTS_DATA("No Mutex Needed", devctl_ap_state)) _NOTE(MUTEX_PROTECTS_DATA(sata_mutex, sata_hba_list)) _NOTE(DATA_READABLE_WITHOUT_LOCK(sata_hba_list)) _NOTE(MUTEX_PROTECTS_DATA(sata_mutex, sata_hba_inst::satahba_next)) _NOTE(MUTEX_PROTECTS_DATA(sata_mutex, sata_hba_inst::satahba_prev)) _NOTE(SCHEME_PROTECTS_DATA("No Mutex Needed", \ sata_hba_inst::satahba_scsi_tran)) _NOTE(SCHEME_PROTECTS_DATA("No Mutex Needed", sata_hba_inst::satahba_tran)) _NOTE(SCHEME_PROTECTS_DATA("No Mutex Needed", sata_hba_inst::satahba_dip)) _NOTE(SCHEME_PROTECTS_DATA("Scheme", sata_hba_inst::satahba_attached)) _NOTE(DATA_READABLE_WITHOUT_LOCK(sata_hba_inst::satahba_dev_port)) _NOTE(MUTEX_PROTECTS_DATA(sata_hba_inst::satahba_mutex, sata_hba_inst::satahba_event_flags)) _NOTE(MUTEX_PROTECTS_DATA(sata_cport_info::cport_mutex, \ sata_cport_info::cport_devp)) _NOTE(DATA_READABLE_WITHOUT_LOCK(sata_cport_info::cport_devp)) _NOTE(SCHEME_PROTECTS_DATA("Scheme", sata_cport_info::cport_addr)) _NOTE(MUTEX_PROTECTS_DATA(sata_cport_info::cport_mutex, \ sata_cport_info::cport_dev_type)) _NOTE(DATA_READABLE_WITHOUT_LOCK(sata_cport_info::cport_dev_type)) _NOTE(MUTEX_PROTECTS_DATA(sata_cport_info::cport_mutex, \ sata_cport_info::cport_state)) _NOTE(DATA_READABLE_WITHOUT_LOCK(sata_cport_info::cport_state)) _NOTE(DATA_READABLE_WITHOUT_LOCK(sata_pmport_info::pmport_dev_type)) _NOTE(DATA_READABLE_WITHOUT_LOCK(sata_pmport_info::pmport_sata_drive)) _NOTE(DATA_READABLE_WITHOUT_LOCK(sata_pmult_info::pmult_dev_port)) _NOTE(DATA_READABLE_WITHOUT_LOCK(sata_pmult_info::pmult_num_dev_ports)) /* End of warlock directives */ /* ************** loadable module configuration functions ************** */ int _init() { int rval; mutex_init(&sata_mutex, NULL, MUTEX_DRIVER, NULL); mutex_init(&sata_event_mutex, NULL, MUTEX_DRIVER, NULL); mutex_init(&sata_log_mutex, NULL, MUTEX_DRIVER, NULL); cv_init(&sata_event_cv, NULL, CV_DRIVER, NULL); if ((rval = mod_install(&modlinkage)) != 0) { #ifdef SATA_DEBUG cmn_err(CE_WARN, "sata: _init: mod_install failed\n"); #endif mutex_destroy(&sata_log_mutex); cv_destroy(&sata_event_cv); mutex_destroy(&sata_event_mutex); mutex_destroy(&sata_mutex); } return (rval); } int _fini() { int rval; if ((rval = mod_remove(&modlinkage)) != 0) return (rval); mutex_destroy(&sata_log_mutex); cv_destroy(&sata_event_cv); mutex_destroy(&sata_event_mutex); mutex_destroy(&sata_mutex); return (rval); } int _info(struct modinfo *modinfop) { return (mod_info(&modlinkage, modinfop)); } /* ********************* SATA HBA entry points ********************* */ /* * Called by SATA HBA from _init(). * Registers HBA driver instance/sata framework pair with scsi framework, by * calling scsi_hba_init(). * * SATA HBA driver cb_ops are ignored - SATA HBA framework cb_ops are used * instead. SATA HBA framework cb_ops pointer overwrites SATA HBA driver * cb_ops pointer in SATA HBA driver dev_ops structure. * SATA HBA framework cb_ops supplies cb_open cb_close and cb_ioctl vectors. * * Return status of the scsi_hba_init() is returned to a calling SATA HBA * driver. */ int sata_hba_init(struct modlinkage *modlp) { int rval; struct dev_ops *hba_ops; SATADBG1(SATA_DBG_HBA_IF, NULL, "sata_hba_init: name %s \n", ((struct modldrv *)(modlp->ml_linkage[0]))->drv_linkinfo); /* * Fill-up cb_ops and dev_ops when necessary */ hba_ops = ((struct modldrv *)(modlp->ml_linkage[0]))->drv_dev_ops; /* * Provide pointer to SATA dev_ops */ hba_ops->devo_cb_ops = &sata_cb_ops; /* * Register SATA HBA with SCSI framework */ if ((rval = scsi_hba_init(modlp)) != 0) { SATADBG1(SATA_DBG_HBA_IF, NULL, "sata_hba_init: scsi hba init failed\n", NULL); return (rval); } return (0); } /* HBA attach stages */ #define HBA_ATTACH_STAGE_SATA_HBA_INST 1 #define HBA_ATTACH_STAGE_SCSI_ATTACHED 2 #define HBA_ATTACH_STAGE_SETUP 4 #define HBA_ATTACH_STAGE_LINKED 8 /* * * Called from SATA HBA driver's attach routine to attach an instance of * the HBA. * * For DDI_ATTACH command: * sata_hba_inst structure is allocated here and initialized with pointers to * SATA framework implementation of required scsi tran functions. * The scsi_tran's tran_hba_private field is used by SATA Framework to point * to the soft structure (sata_hba_inst) allocated by SATA framework for * SATA HBA instance related data. * The scsi_tran's tran_hba_private field is used by SATA framework to * store a pointer to per-HBA-instance of sata_hba_inst structure. * The sata_hba_inst structure is cross-linked to scsi tran structure. * Among other info, a pointer to sata_hba_tran structure is stored in * sata_hba_inst. The sata_hba_inst structures for different HBA instances are * linked together into the list, pointed to by sata_hba_list. * On the first HBA instance attach the sata event thread is initialized. * Attachment points are created for all SATA ports of the HBA being attached. * All HBA instance's SATA ports are probed and type of plugged devices is * determined. For each device of a supported type, a target node is created. * * DDI_SUCCESS is returned when attachment process is successful, * DDI_FAILURE is returned otherwise. * * For DDI_RESUME command: * Not implemented at this time (postponed until phase 2 of the development). */ int sata_hba_attach(dev_info_t *dip, sata_hba_tran_t *sata_tran, ddi_attach_cmd_t cmd) { sata_hba_inst_t *sata_hba_inst; scsi_hba_tran_t *scsi_tran = NULL; int hba_attach_state = 0; SATADBG3(SATA_DBG_HBA_IF, NULL, "sata_hba_attach: node %s (%s%d)\n", ddi_node_name(dip), ddi_driver_name(dip), ddi_get_instance(dip)); if (cmd == DDI_RESUME) { /* * Postponed until phase 2 of the development */ return (DDI_FAILURE); } if (cmd != DDI_ATTACH) { return (DDI_FAILURE); } /* cmd == DDI_ATTACH */ if (sata_validate_sata_hba_tran(dip, sata_tran) != SATA_SUCCESS) { SATA_LOG_D((NULL, CE_WARN, "sata_hba_attach: invalid sata_hba_tran")); return (DDI_FAILURE); } /* * Allocate and initialize SCSI tran structure. * SATA copy of tran_bus_config is provided to create port nodes. */ scsi_tran = scsi_hba_tran_alloc(dip, SCSI_HBA_CANSLEEP); if (scsi_tran == NULL) return (DDI_FAILURE); /* * Allocate soft structure for SATA HBA instance. * There is a separate softstate for each HBA instance. */ sata_hba_inst = kmem_zalloc(sizeof (struct sata_hba_inst), KM_SLEEP); ASSERT(sata_hba_inst != NULL); /* this should not fail */ mutex_init(&sata_hba_inst->satahba_mutex, NULL, MUTEX_DRIVER, NULL); hba_attach_state |= HBA_ATTACH_STAGE_SATA_HBA_INST; /* * scsi_trans's tran_hba_private is used by SATA Framework to point to * soft structure allocated by SATA framework for * SATA HBA instance related data. */ scsi_tran->tran_hba_private = sata_hba_inst; scsi_tran->tran_tgt_private = NULL; scsi_tran->tran_tgt_init = sata_scsi_tgt_init; scsi_tran->tran_tgt_probe = sata_scsi_tgt_probe; scsi_tran->tran_tgt_free = sata_scsi_tgt_free; scsi_tran->tran_start = sata_scsi_start; scsi_tran->tran_reset = sata_scsi_reset; scsi_tran->tran_abort = sata_scsi_abort; scsi_tran->tran_getcap = sata_scsi_getcap; scsi_tran->tran_setcap = sata_scsi_setcap; scsi_tran->tran_init_pkt = sata_scsi_init_pkt; scsi_tran->tran_destroy_pkt = sata_scsi_destroy_pkt; scsi_tran->tran_dmafree = sata_scsi_dmafree; scsi_tran->tran_sync_pkt = sata_scsi_sync_pkt; scsi_tran->tran_reset_notify = NULL; scsi_tran->tran_get_bus_addr = NULL; scsi_tran->tran_quiesce = NULL; scsi_tran->tran_unquiesce = NULL; scsi_tran->tran_bus_reset = NULL; if (scsi_hba_attach_setup(dip, sata_tran->sata_tran_hba_dma_attr, scsi_tran, 0) != DDI_SUCCESS) { #ifdef SATA_DEBUG cmn_err(CE_WARN, "?SATA: %s%d hba scsi attach failed", ddi_driver_name(dip), ddi_get_instance(dip)); #endif goto fail; } hba_attach_state |= HBA_ATTACH_STAGE_SCSI_ATTACHED; if (!ddi_prop_exists(DDI_DEV_T_ANY, dip, DDI_PROP_DONTPASS, "sata")) { if (ddi_prop_update_int(DDI_DEV_T_NONE, dip, "sata", 1) != DDI_PROP_SUCCESS) { SATA_LOG_D((NULL, CE_WARN, "sata_hba_attach: " "failed to create hba sata prop")); goto fail; } } /* * Save pointers in hba instance soft state. */ sata_hba_inst->satahba_scsi_tran = scsi_tran; sata_hba_inst->satahba_tran = sata_tran; sata_hba_inst->satahba_dip = dip; hba_attach_state |= HBA_ATTACH_STAGE_SETUP; /* * Create events thread if not created yet. */ sata_event_thread_control(1); /* * Link this hba instance into the list. */ mutex_enter(&sata_mutex); sata_hba_inst->satahba_next = NULL; sata_hba_inst->satahba_prev = sata_hba_list_tail; if (sata_hba_list == NULL) { sata_hba_list = sata_hba_inst; } if (sata_hba_list_tail != NULL) { sata_hba_list_tail->satahba_next = sata_hba_inst; } sata_hba_list_tail = sata_hba_inst; mutex_exit(&sata_mutex); hba_attach_state |= HBA_ATTACH_STAGE_LINKED; /* * Create SATA HBA devctl minor node for sata_hba_open, close, ioctl * SATA HBA driver should not use its own open/close entry points. * * Make sure that instance number doesn't overflow * when forming minor numbers. */ ASSERT(ddi_get_instance(dip) <= (L_MAXMIN >> INST_MINOR_SHIFT)); if (ddi_create_minor_node(dip, "devctl", S_IFCHR, INST2DEVCTL(ddi_get_instance(dip)), DDI_NT_SATA_NEXUS, 0) != DDI_SUCCESS) { #ifdef SATA_DEBUG cmn_err(CE_WARN, "sata_hba_attach: " "cannot create devctl minor node"); #endif goto fail; } /* * Set-up kstats here, if necessary. * (postponed until phase 2 of the development). */ /* * Probe controller ports. This operation will describe a current * controller/port/multipliers/device configuration and will create * attachment points. * We may end-up with just a controller with no devices attached. */ sata_probe_ports(sata_hba_inst); /* * Create child nodes for all possible target devices currently * attached to controller's ports and port multiplier device ports. */ sata_make_device_nodes(sata_tran->sata_tran_hba_dip, sata_hba_inst); sata_hba_inst->satahba_attached = 1; return (DDI_SUCCESS); fail: if (hba_attach_state & HBA_ATTACH_STAGE_LINKED) { (void) sata_remove_hba_instance(dip); if (sata_hba_list == NULL) sata_event_thread_control(0); } if (hba_attach_state & HBA_ATTACH_STAGE_SETUP) (void) ddi_prop_remove(DDI_DEV_T_ANY, dip, "sata"); if (hba_attach_state & HBA_ATTACH_STAGE_SCSI_ATTACHED) (void) scsi_hba_detach(dip); if (hba_attach_state & HBA_ATTACH_STAGE_SATA_HBA_INST) { mutex_destroy(&sata_hba_inst->satahba_mutex); kmem_free((void *)sata_hba_inst, sizeof (struct sata_hba_inst)); scsi_hba_tran_free(scsi_tran); } sata_log(NULL, CE_WARN, "?SATA: %s%d hba attach failed", ddi_driver_name(dip), ddi_get_instance(dip)); return (DDI_FAILURE); } /* * Called by SATA HBA from to detach an instance of the driver. * * For DDI_DETACH command: * Free local structures allocated for SATA HBA instance during * sata_hba_attach processing. * * Returns DDI_SUCCESS when HBA was detached, DDI_FAILURE otherwise. * * For DDI_SUSPEND command: * Not implemented at this time (postponed until phase 2 of the development) * Returnd DDI_SUCCESS. * * When the last HBA instance is detached, the event daemon is terminated. * * NOTE: cport support only, no port multiplier support. */ int sata_hba_detach(dev_info_t *dip, ddi_detach_cmd_t cmd) { dev_info_t *tdip; sata_hba_inst_t *sata_hba_inst; scsi_hba_tran_t *scsi_hba_tran; sata_cport_info_t *cportinfo; sata_drive_info_t *sdinfo; int ncport; SATADBG3(SATA_DBG_HBA_IF, NULL, "sata_hba_detach: node %s (%s%d)\n", ddi_node_name(dip), ddi_driver_name(dip), ddi_get_instance(dip)); switch (cmd) { case DDI_DETACH: if ((scsi_hba_tran = ddi_get_driver_private(dip)) == NULL) return (DDI_FAILURE); sata_hba_inst = scsi_hba_tran->tran_hba_private; if (sata_hba_inst == NULL) return (DDI_FAILURE); if (scsi_hba_detach(dip) == DDI_FAILURE) { sata_hba_inst->satahba_attached = 1; return (DDI_FAILURE); } /* * Free all target nodes - at this point * devices should be at least offlined * otherwise scsi_hba_detach() should not be called. */ for (ncport = 0; ncport < SATA_NUM_CPORTS(sata_hba_inst); ncport++) { cportinfo = SATA_CPORT_INFO(sata_hba_inst, ncport); if (cportinfo->cport_dev_type != SATA_DTYPE_PMULT) { sdinfo = SATA_CPORTINFO_DRV_INFO(cportinfo); if (sdinfo != NULL) { tdip = sata_get_target_dip(dip, ncport); if (tdip != NULL) { if (ndi_devi_offline(tdip, NDI_DEVI_REMOVE) != NDI_SUCCESS) { SATA_LOG_D(( sata_hba_inst, CE_WARN, "sata_hba_detach: " "Target node not " "removed !")); return (DDI_FAILURE); } } } } } /* * Disable sata event daemon processing for this HBA */ sata_hba_inst->satahba_attached = 0; /* * Remove event daemon thread, if it is last HBA instance. */ mutex_enter(&sata_mutex); if (sata_hba_list->satahba_next == NULL) { mutex_exit(&sata_mutex); sata_event_thread_control(0); mutex_enter(&sata_mutex); } mutex_exit(&sata_mutex); /* Remove this HBA instance from the HBA list */ sata_remove_hba_instance(dip); /* * At this point there should be no target nodes attached. * Detach and destroy device and port info structures. */ for (ncport = 0; ncport < SATA_NUM_CPORTS(sata_hba_inst); ncport++) { cportinfo = SATA_CPORT_INFO(sata_hba_inst, ncport); if (cportinfo->cport_dev_type != SATA_DTYPE_PMULT) { sdinfo = cportinfo->cport_devp.cport_sata_drive; if (sdinfo != NULL) { /* Release device structure */ kmem_free(sdinfo, sizeof (sata_drive_info_t)); } /* Release cport info */ mutex_destroy(&cportinfo->cport_mutex); kmem_free(cportinfo, sizeof (sata_cport_info_t)); } } scsi_hba_tran_free(sata_hba_inst->satahba_scsi_tran); mutex_destroy(&sata_hba_inst->satahba_mutex); kmem_free((void *)sata_hba_inst, sizeof (struct sata_hba_inst)); return (DDI_SUCCESS); case DDI_SUSPEND: /* * Postponed until phase 2 */ return (DDI_FAILURE); default: return (DDI_FAILURE); } } /* * Called by an HBA drive from _fini() routine. * Unregisters SATA HBA instance/SATA framework pair from the scsi framework. */ void sata_hba_fini(struct modlinkage *modlp) { SATADBG1(SATA_DBG_HBA_IF, NULL, "sata_hba_fini: name %s\n", ((struct modldrv *)(modlp->ml_linkage[0]))->drv_linkinfo); scsi_hba_fini(modlp); } /* * Default open and close routine for sata_hba framework. * */ /* * Open devctl node. * * Returns: * 0 if node was open successfully, error code otherwise. * * */ static int sata_hba_open(dev_t *devp, int flags, int otyp, cred_t *credp) { #ifndef __lock_lint _NOTE(ARGUNUSED(credp)) #endif int rv = 0; dev_info_t *dip; scsi_hba_tran_t *scsi_hba_tran; sata_hba_inst_t *sata_hba_inst; SATADBG1(SATA_DBG_IOCTL_IF, NULL, "sata_hba_open: entered", NULL); if (otyp != OTYP_CHR) return (EINVAL); dip = sata_devt_to_devinfo(*devp); if (dip == NULL) return (ENXIO); if ((scsi_hba_tran = ddi_get_driver_private(dip)) == NULL) return (ENXIO); sata_hba_inst = scsi_hba_tran->tran_hba_private; if (sata_hba_inst == NULL || sata_hba_inst->satahba_attached == 0) return (ENXIO); mutex_enter(&sata_mutex); if (flags & FEXCL) { if (sata_hba_inst->satahba_open_flag != 0) { rv = EBUSY; } else { sata_hba_inst->satahba_open_flag = SATA_DEVCTL_EXOPENED; } } else { if (sata_hba_inst->satahba_open_flag == SATA_DEVCTL_EXOPENED) { rv = EBUSY; } else { sata_hba_inst->satahba_open_flag = SATA_DEVCTL_SOPENED; } } mutex_exit(&sata_mutex); return (rv); } /* * Close devctl node. * Returns: * 0 if node was closed successfully, error code otherwise. * */ static int sata_hba_close(dev_t dev, int flag, int otyp, cred_t *credp) { #ifndef __lock_lint _NOTE(ARGUNUSED(credp)) _NOTE(ARGUNUSED(flag)) #endif dev_info_t *dip; scsi_hba_tran_t *scsi_hba_tran; sata_hba_inst_t *sata_hba_inst; SATADBG1(SATA_DBG_IOCTL_IF, NULL, "sata_hba_close: entered", NULL); if (otyp != OTYP_CHR) return (EINVAL); dip = sata_devt_to_devinfo(dev); if (dip == NULL) return (ENXIO); if ((scsi_hba_tran = ddi_get_driver_private(dip)) == NULL) return (ENXIO); sata_hba_inst = scsi_hba_tran->tran_hba_private; if (sata_hba_inst == NULL || sata_hba_inst->satahba_attached == 0) return (ENXIO); mutex_enter(&sata_mutex); sata_hba_inst->satahba_open_flag = 0; mutex_exit(&sata_mutex); return (0); } /* * Standard IOCTL commands for SATA hotplugging. * Implemented DEVCTL_AP commands: * DEVCTL_AP_CONNECT * DEVCTL_AP_DISCONNECT * DEVCTL_AP_CONFIGURE * DEVCTL_UNCONFIGURE * DEVCTL_AP_CONTROL * * Commands passed to default ndi ioctl handler: * DEVCTL_DEVICE_GETSTATE * DEVCTL_DEVICE_ONLINE * DEVCTL_DEVICE_OFFLINE * DEVCTL_DEVICE_REMOVE * DEVCTL_DEVICE_INSERT * DEVCTL_BUS_GETSTATE * * All other cmds are passed to HBA if it provide ioctl handler, or failed * if not. * * Returns: * 0 if successful, * error code if operation failed. * * NOTE: Port Multiplier is not supported. * */ static int sata_hba_ioctl(dev_t dev, int cmd, intptr_t arg, int mode, cred_t *credp, int *rvalp) { #ifndef __lock_lint _NOTE(ARGUNUSED(credp)) _NOTE(ARGUNUSED(rvalp)) #endif int rv = 0; int32_t comp_port = -1; dev_info_t *dip, *tdip; devctl_ap_state_t ap_state; struct devctl_iocdata *dcp = NULL; scsi_hba_tran_t *scsi_hba_tran; sata_hba_inst_t *sata_hba_inst; sata_device_t sata_device; sata_drive_info_t *sdinfo; sata_cport_info_t *cportinfo; int cport, pmport, qual; int rval = SATA_SUCCESS; dip = sata_devt_to_devinfo(dev); if (dip == NULL) return (ENXIO); if ((scsi_hba_tran = ddi_get_driver_private(dip)) == NULL) return (ENXIO); sata_hba_inst = scsi_hba_tran->tran_hba_private; if (sata_hba_inst == NULL) return (ENXIO); if (sata_hba_inst->satahba_tran == NULL) return (ENXIO); switch (cmd) { case DEVCTL_DEVICE_GETSTATE: case DEVCTL_DEVICE_ONLINE: case DEVCTL_DEVICE_OFFLINE: case DEVCTL_DEVICE_REMOVE: case DEVCTL_BUS_GETSTATE: /* * There may be more cases that we want to pass to default * handler rather then fail them. */ return (ndi_devctl_ioctl(dip, cmd, arg, mode, 0)); } /* read devctl ioctl data */ if (cmd != DEVCTL_AP_CONTROL) { if (ndi_dc_allochdl((void *)arg, &dcp) != NDI_SUCCESS) return (EFAULT); if ((comp_port = sata_get_port_num(sata_hba_inst, dcp)) == -1) { if (dcp) ndi_dc_freehdl(dcp); return (EINVAL); } cport = SCSI_TO_SATA_CPORT(comp_port); pmport = SCSI_TO_SATA_PMPORT(comp_port); /* Only cport is considered now, i.e. SATA_ADDR_CPORT */ qual = SATA_ADDR_CPORT; if (sata_validate_sata_address(sata_hba_inst, cport, pmport, qual) != 0) { ndi_dc_freehdl(dcp); return (EINVAL); } cportinfo = SATA_CPORT_INFO(sata_hba_inst, cport); mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); if (cportinfo->cport_event_flags & SATA_EVNT_LOCK_PORT_BUSY) { /* * Cannot process ioctl request now. Come back later. */ mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); ndi_dc_freehdl(dcp); return (EBUSY); } /* Block event processing for this port */ cportinfo->cport_event_flags |= SATA_APCTL_LOCK_PORT_BUSY; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); sata_device.satadev_addr.cport = cport; sata_device.satadev_addr.pmport = pmport; sata_device.satadev_addr.qual = SATA_ADDR_CPORT; sata_device.satadev_rev = SATA_DEVICE_REV; } switch (cmd) { case DEVCTL_AP_DISCONNECT: /* * Normally, cfgadm sata plugin will try to offline * (unconfigure) device before this request. Nevertheless, * if a device is still configured, we need to * attempt to offline and unconfigure device first, and we will * deactivate the port regardless of the unconfigure * operation results. * * DEVCTL_AP_DISCONNECT invokes * sata_hba_inst->satahba_tran-> * sata_tran_hotplug_ops->sata_tran_port_deactivate(). * If successful, the device structure (if any) attached * to a port is removed and state of the port marked * appropriately. * Failure of the port_deactivate may keep port in * the active state, or may fail the port. */ /* Check the current state of the port */ if (sata_reprobe_port(sata_hba_inst, &sata_device) != SATA_SUCCESS) { rv = EIO; break; } mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); if (cportinfo->cport_state & (SATA_PSTATE_SHUTDOWN | SATA_PSTATE_FAILED)) { mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); rv = EIO; break; } /* Sanity check */ if (SATA_PORT_DEACTIVATE_FUNC(sata_hba_inst) == NULL) { /* No physical port deactivation supported. */ break; } /* * set port's dev_state to not ready - this will disable * an access to an attached device. */ cportinfo->cport_state &= ~SATA_STATE_READY; if (cportinfo->cport_dev_type != SATA_DTYPE_NONE) { sdinfo = cportinfo->cport_devp.cport_sata_drive; ASSERT(sdinfo != NULL); if ((sdinfo->satadrv_type & (SATA_VALID_DEV_TYPE))) { /* * If a target node exists, try to offline * a device and remove target node. */ mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); tdip = sata_get_target_dip(dip, comp_port); if (tdip != NULL) { /* target node exist */ if (ndi_devi_offline(tdip, NDI_DEVI_REMOVE) != NDI_SUCCESS) { /* * Problem * A target node remained * attached. This happens when * the file was open or a node * was waiting for resources. * Cannot do anything about it. */ SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_hba_ioctl: " "disconnect: cannot " "remove target node!!!")); } } mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); /* * Remove and release sata_drive_info * structure. */ if (SATA_CPORTINFO_DRV_INFO(cportinfo) != NULL) { SATA_CPORTINFO_DRV_INFO(cportinfo) = NULL; (void) kmem_free((void *)sdinfo, sizeof (sata_drive_info_t)); cportinfo->cport_dev_type = SATA_DTYPE_NONE; } } /* * Note: PMult info requires different handling. * Put PMult handling code here, when PMult is * supported. */ } mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); /* Just ask HBA driver to deactivate port */ sata_device.satadev_addr.qual = SATA_ADDR_DCPORT; rval = (*SATA_PORT_DEACTIVATE_FUNC(sata_hba_inst)) (dip, &sata_device); /* * Generate sysevent - EC_DR / ESC_DR_AP_STATE_CHANGE * without the hint. */ sata_gen_sysevent(sata_hba_inst, &sata_device.satadev_addr, SE_NO_HINT); mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); sata_update_port_info(sata_hba_inst, &sata_device); if (rval != SATA_SUCCESS) { /* * Port deactivation failure - do not * change port state unless the state * returned by HBA indicates a port failure. */ if (sata_device.satadev_state & SATA_PSTATE_FAILED) cportinfo->cport_state = SATA_PSTATE_FAILED; rv = EIO; } else { /* * Deactivation succeded. From now on the framework * will not know what is happening to the device, until * the port is activated again. */ cportinfo->cport_state |= SATA_PSTATE_SHUTDOWN; } mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); break; case DEVCTL_AP_UNCONFIGURE: /* * The unconfigure operation uses generic nexus operation to * offline a device. It leaves a target device node attached. * and obviously sata_drive_info attached as well, because * from the hardware point of view nothing has changed. */ if ((tdip = sata_get_target_dip(dip, comp_port)) != NULL) { if (ndi_devi_offline(tdip, NDI_UNCONFIG) != NDI_SUCCESS) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_hba_ioctl: unconfigure: " "failed to unconfigure " "device at cport %d", cport)); rv = EIO; } /* * The target node devi_state should be marked with * DEVI_DEVICE_OFFLINE by ndi_devi_offline(). * This would be the indication for cfgadm that * the AP node occupant state is 'unconfigured'. */ } else { /* * This would indicate a failure on the part of cfgadm * to detect correct state of the node prior to this * call - one cannot unconfigure non-existing device. */ SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_hba_ioctl: unconfigure: " "attempt to unconfigure non-existing device " "at cport %d", cport)); rv = ENXIO; } break; case DEVCTL_AP_CONNECT: { /* * The sata cfgadm pluging will invoke this operation only if * port was found in the disconnect state (failed state * is also treated as the disconnected state). * DEVCTL_AP_CONNECT would invoke * sata_hba_inst->satahba_tran-> * sata_tran_hotplug_ops->sata_tran_port_activate(). * If successful and a device is found attached to the port, * the initialization sequence is executed to attach * a device structure to a port structure. The device is not * set in configured state (system-wise) by this operation. * The state of the port and a device would be set * appropriately. * * Note, that activating the port may generate link events, * so is is important that following processing and the * event processing does not interfere with each other! * * This operation may remove port failed state and will * try to make port active and in good standing. */ /* We only care about host sata cport for now */ if (SATA_PORT_ACTIVATE_FUNC(sata_hba_inst) != NULL) { /* Just let HBA driver to activate port */ if ((*SATA_PORT_ACTIVATE_FUNC(sata_hba_inst)) (dip, &sata_device) != SATA_SUCCESS) { /* * Port activation failure. */ mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); sata_update_port_info(sata_hba_inst, &sata_device); if (sata_device.satadev_state & SATA_PSTATE_FAILED) { cportinfo->cport_state = SATA_PSTATE_FAILED; } mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_hba_ioctl: connect: " "failed to activate SATA cport %d", cport)); rv = EIO; break; } } /* Virgin port state - will be updated by the port re-probe. */ mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); cportinfo->cport_state = 0; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); if (sata_reprobe_port(sata_hba_inst, &sata_device) == SATA_FAILURE) rv = EIO; /* * Generate sysevent - EC_DR / ESC_DR_AP_STATE_CHANGE * without the hint */ sata_gen_sysevent(sata_hba_inst, &sata_device.satadev_addr, SE_NO_HINT); /* * If there is a device attached to the port, emit * a message. */ if (cportinfo->cport_dev_type != SATA_DTYPE_NONE) { sata_log(sata_hba_inst, CE_WARN, "SATA device detected at port %d", cport); } break; } case DEVCTL_AP_CONFIGURE: { boolean_t target = TRUE; /* * A port may be in an active or shutdown state. * If port is in a failed state, operation is aborted - one * has to use explicit connect or port activate request * to try to get a port into non-failed mode. * * If a port is in a shutdown state, arbitrarily invoke * sata_tran_port_activate() prior to any other operation. * * Verify that port state is READY and there is a device * of a supported type attached to this port. * If target node exists, a device was most likely offlined. * If target node does not exist, create a target node an * attempt to online it. * * * NO PMult or devices beyond PMult are supported yet. */ /* We only care about host controller's sata cport for now. */ if (cportinfo->cport_state & SATA_PSTATE_FAILED) { rv = ENXIO; break; } /* Check the current state of the port */ sata_device.satadev_addr.qual = SATA_ADDR_CPORT; rval = (*SATA_PROBE_PORT_FUNC(sata_hba_inst)) (dip, &sata_device); mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); sata_update_port_info(sata_hba_inst, &sata_device); if (rval != SATA_SUCCESS || (sata_device.satadev_state & SATA_PSTATE_FAILED)) { cportinfo->cport_state = SATA_PSTATE_FAILED; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); rv = EIO; break; } if (cportinfo->cport_state & SATA_PSTATE_SHUTDOWN) { target = FALSE; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); if (SATA_PORT_ACTIVATE_FUNC(sata_hba_inst) != NULL) { /* Just let HBA driver to activate port */ if ((*SATA_PORT_ACTIVATE_FUNC(sata_hba_inst)) (dip, &sata_device) != SATA_SUCCESS) { /* * Port activation failure - do not * change port state unless the state * returned by HBA indicates a port * failure. */ mutex_enter(&SATA_CPORT_INFO( sata_hba_inst, cport)->cport_mutex); sata_update_port_info(sata_hba_inst, &sata_device); if (sata_device.satadev_state & SATA_PSTATE_FAILED) { cportinfo->cport_state = SATA_PSTATE_FAILED; } mutex_exit(&SATA_CPORT_INFO( sata_hba_inst, cport)->cport_mutex); SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_hba_ioctl: configure: " "failed to activate SATA cport %d", cport)); rv = EIO; break; } } /* * Generate sysevent - EC_DR / ESC_DR_AP_STATE_CHANGE * without the hint. */ sata_gen_sysevent(sata_hba_inst, &sata_device.satadev_addr, SE_NO_HINT); mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); /* Virgin port state */ cportinfo->cport_state = 0; } /* * Always reprobe port, to get current device info. */ mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); if (sata_reprobe_port(sata_hba_inst, &sata_device) != SATA_SUCCESS) { rv = EIO; break; } if (target == FALSE && cportinfo->cport_dev_type != SATA_DTYPE_NONE) { /* * That's the transition from "inactive" port * to active one with device attached. */ sata_log(sata_hba_inst, CE_WARN, "SATA device detected at port %d", cport); } /* * This is where real configure starts. * Change following check for PMult support. */ if (!(sata_device.satadev_type & SATA_VALID_DEV_TYPE)) { /* No device to configure */ rv = ENXIO; /* No device to configure */ break; } /* * Here we may have a device in reset condition, * but because we are just configuring it, there is * no need to process the reset other than just * to clear device reset condition in the HBA driver. * Setting the flag SATA_EVNT_CLEAR_DEVICE_RESET will * cause a first command sent the HBA driver with the request * to clear device reset condition. */ mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); sdinfo = sata_get_device_info(sata_hba_inst, &sata_device); if (sdinfo == NULL) { rv = ENXIO; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); break; } if (sdinfo->satadrv_event_flags & (SATA_EVNT_DEVICE_RESET | SATA_EVNT_INPROC_DEVICE_RESET)) sdinfo->satadrv_event_flags = 0; sdinfo->satadrv_event_flags |= SATA_EVNT_CLEAR_DEVICE_RESET; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); if ((tdip = sata_get_target_dip(dip, comp_port)) != NULL) { /* target node still exists */ if (ndi_devi_online(tdip, 0) != NDI_SUCCESS) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_hba_ioctl: configure: " "onlining device at cport %d failed", cport)); rv = EIO; break; } } else { /* * No target node - need to create a new target node. */ tdip = sata_create_target_node(dip, sata_hba_inst, &sata_device.satadev_addr); if (tdip == NULL) { /* configure failed */ SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_hba_ioctl: configure: " "configuring device at cport %d " "failed", cport)); rv = EIO; break; } } break; } case DEVCTL_AP_GETSTATE: sata_cfgadm_state(sata_hba_inst, comp_port, &ap_state); ap_state.ap_last_change = (time_t)-1; ap_state.ap_error_code = 0; ap_state.ap_in_transition = 0; /* Copy the return AP-state information to the user space */ if (ndi_dc_return_ap_state(&ap_state, dcp) != NDI_SUCCESS) { rv = EFAULT; } break; case DEVCTL_AP_CONTROL: { /* * Generic devctl for hardware specific functionality */ sata_ioctl_data_t ioc; ASSERT(dcp == NULL); /* Copy in user ioctl data first */ #ifdef _MULTI_DATAMODEL if (ddi_model_convert_from(mode & FMODELS) == DDI_MODEL_ILP32) { sata_ioctl_data_32_t ioc32; if (ddi_copyin((void *)arg, (void *)&ioc32, sizeof (ioc32), mode) != 0) { rv = EFAULT; break; } ioc.cmd = (uint_t)ioc32.cmd; ioc.port = (uint_t)ioc32.port; ioc.get_size = (uint_t)ioc32.get_size; ioc.buf = (caddr_t)(uintptr_t)ioc32.buf; ioc.bufsiz = (uint_t)ioc32.bufsiz; ioc.misc_arg = (uint_t)ioc32.misc_arg; } else #endif /* _MULTI_DATAMODEL */ if (ddi_copyin((void *)arg, (void *)&ioc, sizeof (ioc), mode) != 0) { return (EFAULT); } SATADBG2(SATA_DBG_IOCTL_IF, sata_hba_inst, "sata_hba_ioctl: DEVCTL_AP_CONTROL " "cmd 0x%x, port 0x%x", ioc.cmd, ioc.port); /* * To avoid BE/LE and 32/64 issues, a get_size always returns * a 32-bit number. */ if (ioc.get_size != 0 && ioc.bufsiz != (sizeof (uint32_t))) { return (EINVAL); } /* validate address */ cport = SCSI_TO_SATA_CPORT(ioc.port); pmport = SCSI_TO_SATA_PMPORT(ioc.port); qual = SCSI_TO_SATA_ADDR_QUAL(ioc.port); /* Override address qualifier - handle cport only for now */ qual = SATA_ADDR_CPORT; if (sata_validate_sata_address(sata_hba_inst, cport, pmport, qual) != 0) return (EINVAL); cportinfo = SATA_CPORT_INFO(sata_hba_inst, cport); mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); /* Is the port locked by event processing daemon ? */ if (cportinfo->cport_event_flags & SATA_EVNT_LOCK_PORT_BUSY) { /* * Cannot process ioctl request now. Come back later */ mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); return (EBUSY); } /* Block event processing for this port */ cportinfo->cport_event_flags |= SATA_APCTL_LOCK_PORT_BUSY; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); sata_device.satadev_addr.cport = cport; sata_device.satadev_addr.pmport = pmport; sata_device.satadev_rev = SATA_DEVICE_REV; switch (ioc.cmd) { case SATA_CFGA_RESET_PORT: /* * There is no protection here for configured * device. */ /* Sanity check */ if (SATA_RESET_DPORT_FUNC(sata_hba_inst) == NULL) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_hba_ioctl: " "sata_hba_tran missing required " "function sata_tran_reset_dport")); rv = EINVAL; break; } /* handle cport only for now */ sata_device.satadev_addr.qual = SATA_ADDR_CPORT; if ((*SATA_RESET_DPORT_FUNC(sata_hba_inst)) (dip, &sata_device) != SATA_SUCCESS) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_hba_ioctl: reset port: " "failed cport %d pmport %d", cport, pmport)); mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); sata_update_port_info(sata_hba_inst, &sata_device); SATA_CPORT_STATE(sata_hba_inst, cport) = SATA_PSTATE_FAILED; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); rv = EIO; } /* * Since the port was reset, it should be probed and * attached device reinitialized. At this point the * port state is unknown - it's state is HBA-specific. * Re-probe port to get its state. */ if (sata_reprobe_port(sata_hba_inst, &sata_device) != SATA_SUCCESS) { rv = EIO; break; } break; case SATA_CFGA_RESET_DEVICE: /* * There is no protection here for configured * device. */ /* Sanity check */ if (SATA_RESET_DPORT_FUNC(sata_hba_inst) == NULL) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_hba_ioctl: " "sata_hba_tran missing required " "function sata_tran_reset_dport")); rv = EINVAL; break; } /* handle only device attached to cports, for now */ sata_device.satadev_addr.qual = SATA_ADDR_DCPORT; mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); sdinfo = sata_get_device_info(sata_hba_inst, &sata_device); if (sdinfo == NULL) { mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); rv = EINVAL; break; } mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); /* only handle cport for now */ sata_device.satadev_addr.qual = SATA_ADDR_DCPORT; if ((*SATA_RESET_DPORT_FUNC(sata_hba_inst)) (dip, &sata_device) != SATA_SUCCESS) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_hba_ioctl: reset device: failed " "cport %d pmport %d", cport, pmport)); mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); sata_update_port_info(sata_hba_inst, &sata_device); /* * Device info structure remains * attached. Another device reset or * port disconnect/connect and re-probing is * needed to change it's state */ sdinfo->satadrv_state &= ~SATA_STATE_READY; sdinfo->satadrv_state |= SATA_DSTATE_FAILED; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); rv = EIO; } /* * Since the device was reset, we expect reset event * to be reported and processed. */ break; case SATA_CFGA_RESET_ALL: { int tcport; /* * There is no protection here for configured * devices. */ /* Sanity check */ if (SATA_RESET_DPORT_FUNC(sata_hba_inst) == NULL) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_hba_ioctl: " "sata_hba_tran missing required " "function sata_tran_reset_dport")); rv = EINVAL; break; } /* * Need to lock all ports, not just one. * If any port is locked by event processing, fail * the whole operation. * One port is already locked, but for simplicity * lock it again. */ for (tcport = 0; tcport < SATA_NUM_CPORTS(sata_hba_inst); tcport++) { mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, tcport)->cport_mutex); if (((SATA_CPORT_INFO(sata_hba_inst, tcport)-> cport_event_flags) & SATA_EVNT_LOCK_PORT_BUSY) != 0) { rv = EBUSY; mutex_exit( &SATA_CPORT_INFO(sata_hba_inst, tcport)->cport_mutex); break; } else { SATA_CPORT_INFO(sata_hba_inst, tcport)->cport_event_flags |= SATA_APCTL_LOCK_PORT_BUSY; } mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, tcport)->cport_mutex); } if (rv == 0) { /* * All cports successfully locked. * Reset main SATA controller only for now - * no PMult. */ sata_device.satadev_addr.qual = SATA_ADDR_CNTRL; if ((*SATA_RESET_DPORT_FUNC(sata_hba_inst)) (dip, &sata_device) != SATA_SUCCESS) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_hba_ioctl: reset controller " "failed")); rv = EIO; } /* * Since ports were reset, they should be * re-probed and attached devices * reinitialized. * At this point port states are unknown, * Re-probe ports to get their state - * cports only for now. */ for (tcport = 0; tcport < SATA_NUM_CPORTS(sata_hba_inst); tcport++) { sata_device.satadev_addr.cport = tcport; sata_device.satadev_addr.qual = SATA_ADDR_CPORT; if (sata_reprobe_port(sata_hba_inst, &sata_device) != SATA_SUCCESS) rv = EIO; } } /* * Unlock all ports */ for (tcport = 0; tcport < SATA_NUM_CPORTS(sata_hba_inst); tcport++) { mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, tcport)->cport_mutex); SATA_CPORT_INFO(sata_hba_inst, tcport)-> cport_event_flags &= ~SATA_APCTL_LOCK_PORT_BUSY; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, tcport)->cport_mutex); } /* * This operation returns EFAULT if either reset * controller failed or a re-probbing of any ports * failed. * We return here, because common return is for * a single cport operation. */ return (rv); } case SATA_CFGA_PORT_DEACTIVATE: /* Sanity check */ if (SATA_PORT_DEACTIVATE_FUNC(sata_hba_inst) == NULL) { rv = ENOTSUP; break; } /* * Arbitrarily unconfigure attached device, if any. * Even if the unconfigure fails, proceed with the * port deactivation. */ /* Handle only device attached to cports, for now */ sata_device.satadev_addr.qual = SATA_ADDR_DCPORT; mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); cportinfo->cport_state &= ~SATA_STATE_READY; if (cportinfo->cport_dev_type != SATA_DTYPE_NONE) { /* * Handle only device attached to cports, * for now */ sata_device.satadev_addr.qual = SATA_ADDR_DCPORT; sdinfo = sata_get_device_info(sata_hba_inst, &sata_device); if (sdinfo != NULL && (sdinfo->satadrv_type & SATA_VALID_DEV_TYPE)) { /* * If a target node exists, try to * offline a device and remove target * node. */ mutex_exit(&SATA_CPORT_INFO( sata_hba_inst, cport)->cport_mutex); tdip = sata_get_target_dip(dip, cport); if (tdip != NULL) { /* target node exist */ SATADBG1(SATA_DBG_IOCTL_IF, sata_hba_inst, "sata_hba_ioctl: " "port deactivate: " "target node exists.", NULL); if (ndi_devi_offline(tdip, NDI_UNCONFIG) != NDI_SUCCESS) { SATA_LOG_D(( sata_hba_inst, CE_WARN, "sata_hba_ioctl:" "port deactivate: " "failed to " "unconfigure " "device at cport " "%d", cport)); } if (ndi_devi_offline(tdip, NDI_DEVI_REMOVE) != NDI_SUCCESS) { /* * Problem; * target node remained * attached. * Too bad... */ SATA_LOG_D(( sata_hba_inst, CE_WARN, "sata_hba_ioctl: " "port deactivate: " "failed to " "unconfigure " "device at " "cport %d", cport)); } } mutex_enter(&SATA_CPORT_INFO( sata_hba_inst, cport)->cport_mutex); /* * In any case, * remove and release sata_drive_info * structure. * (cport attached device ony, for now) */ SATA_CPORTINFO_DRV_INFO(cportinfo) = NULL; (void) kmem_free((void *)sdinfo, sizeof (sata_drive_info_t)); cportinfo->cport_dev_type = SATA_DTYPE_NONE; } /* * Note: PMult info requires different * handling. This comment is a placeholder for * a code handling PMult, to be implemented * in phase 2. */ } cportinfo->cport_state &= ~(SATA_STATE_PROBED | SATA_STATE_PROBING); mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); /* handle cport only for now */ sata_device.satadev_addr.qual = SATA_ADDR_CPORT; /* Just let HBA driver to deactivate port */ rval = (*SATA_PORT_DEACTIVATE_FUNC(sata_hba_inst)) (dip, &sata_device); /* * Generate sysevent - * EC_DR / ESC_DR_AP_STATE_CHANGE * without the hint */ sata_gen_sysevent(sata_hba_inst, &sata_device.satadev_addr, SE_NO_HINT); mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); sata_update_port_info(sata_hba_inst, &sata_device); if (rval != SATA_SUCCESS) { /* * Port deactivation failure - do not * change port state unless the state * returned by HBA indicates a port failure. */ if (sata_device.satadev_state & SATA_PSTATE_FAILED) { SATA_CPORT_STATE(sata_hba_inst, cport) = SATA_PSTATE_FAILED; } SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_hba_ioctl: port deactivate: " "cannot deactivate SATA cport %d", cport)); rv = EIO; } else { cportinfo->cport_state |= SATA_PSTATE_SHUTDOWN; } mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); break; case SATA_CFGA_PORT_ACTIVATE: { boolean_t dev_existed = TRUE; /* Sanity check */ if (SATA_PORT_ACTIVATE_FUNC(sata_hba_inst) == NULL) { rv = ENOTSUP; break; } /* handle cport only for now */ if (cportinfo->cport_state & SATA_PSTATE_SHUTDOWN || cportinfo->cport_dev_type == SATA_DTYPE_NONE) dev_existed = FALSE; sata_device.satadev_addr.qual = SATA_ADDR_CPORT; /* Just let HBA driver to activate port */ if ((*SATA_PORT_ACTIVATE_FUNC(sata_hba_inst)) (dip, &sata_device) != SATA_SUCCESS) { /* * Port activation failure - do not * change port state unless the state * returned by HBA indicates a port failure. */ mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); sata_update_port_info(sata_hba_inst, &sata_device); if (sata_device.satadev_state & SATA_PSTATE_FAILED) { SATA_CPORT_STATE(sata_hba_inst, cport) = SATA_PSTATE_FAILED; } mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_hba_ioctl: port activate: " "cannot activate SATA cport %d", cport)); rv = EIO; break; } mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); cportinfo->cport_state &= ~SATA_PSTATE_SHUTDOWN; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); /* * Re-probe port to find its current state and * possibly attached device. * Port re-probing may change the cportinfo device * type if device is found attached. * If port probing failed, the device type would be * set to SATA_DTYPE_NONE. */ (void) sata_reprobe_port(sata_hba_inst, &sata_device); /* * Generate sysevent - * EC_DR / ESC_DR_AP_STATE_CHANGE * without the hint. */ sata_gen_sysevent(sata_hba_inst, &sata_device.satadev_addr, SE_NO_HINT); if (dev_existed == FALSE && cportinfo->cport_dev_type != SATA_DTYPE_NONE) { /* * That's the transition from "inactive" port * state or active port without a device * attached to the active port state with * a device attached. */ sata_log(sata_hba_inst, CE_WARN, "SATA device detected at port %d", cport); } break; } case SATA_CFGA_PORT_SELF_TEST: /* Sanity check */ if (SATA_SELFTEST_FUNC(sata_hba_inst) == NULL) { rv = ENOTSUP; break; } /* * There is no protection here for a configured * device attached to this port. */ /* only handle cport for now */ sata_device.satadev_addr.qual = SATA_ADDR_CPORT; if ((*SATA_SELFTEST_FUNC(sata_hba_inst)) (dip, &sata_device) != SATA_SUCCESS) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_hba_ioctl: port selftest: " "failed cport %d pmport %d", cport, pmport)); mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); sata_update_port_info(sata_hba_inst, &sata_device); SATA_CPORT_STATE(sata_hba_inst, cport) = SATA_PSTATE_FAILED; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); rv = EIO; break; } /* * Since the port was reset, it should be probed and * attached device reinitialized. At this point the * port state is unknown - it's state is HBA-specific. * Force port re-probing to get it into a known state. */ if (sata_reprobe_port(sata_hba_inst, &sata_device) != SATA_SUCCESS) { rv = EIO; break; } break; case SATA_CFGA_GET_DEVICE_PATH: { char path[MAXPATHLEN]; uint32_t size; (void) strcpy(path, "/devices"); if ((tdip = sata_get_target_dip(dip, ioc.port)) == NULL) { /* * No such device. * If this is a request for a size, do not * return EINVAL for non-exisiting target, * because cfgadm will indicate a meaningless * ioctl failure. * If this is a real request for a path, * indicate invalid argument. */ if (!ioc.get_size) { rv = EINVAL; break; } } else { (void) ddi_pathname(tdip, path + strlen(path)); } size = strlen(path) + 1; if (ioc.get_size) { if (ddi_copyout((void *)&size, ioc.buf, ioc.bufsiz, mode) != 0) { rv = EFAULT; } } else { if (ioc.bufsiz != size) { rv = EINVAL; } else if (ddi_copyout((void *)&path, ioc.buf, ioc.bufsiz, mode) != 0) { rv = EFAULT; } } break; } case SATA_CFGA_GET_AP_TYPE: { uint32_t type_len; const char *ap_type; /* cport only, no port multiplier support */ switch (SATA_CPORT_DEV_TYPE(sata_hba_inst, cport)) { case SATA_DTYPE_NONE: ap_type = "port"; break; case SATA_DTYPE_ATADISK: ap_type = "disk"; break; case SATA_DTYPE_ATAPICD: ap_type = "cd/dvd"; break; case SATA_DTYPE_PMULT: ap_type = "pmult"; break; case SATA_DTYPE_UNKNOWN: ap_type = "unknown"; break; default: ap_type = "unsupported"; break; } /* end of dev_type switch */ type_len = strlen(ap_type) + 1; if (ioc.get_size) { if (ddi_copyout((void *)&type_len, ioc.buf, ioc.bufsiz, mode) != 0) { rv = EFAULT; break; } } else { if (ioc.bufsiz != type_len) { rv = EINVAL; break; } if (ddi_copyout((void *)ap_type, ioc.buf, ioc.bufsiz, mode) != 0) { rv = EFAULT; break; } } break; } case SATA_CFGA_GET_MODEL_INFO: { uint32_t info_len; char ap_info[sizeof (sdinfo->satadrv_id.ai_model) + 1]; /* * This operation should return to cfgadm the * device model information string */ mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); /* only handle device connected to cport for now */ sata_device.satadev_addr.qual = SATA_ADDR_DCPORT; sdinfo = sata_get_device_info(sata_hba_inst, &sata_device); if (sdinfo == NULL) { rv = EINVAL; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); break; } bcopy(sdinfo->satadrv_id.ai_model, ap_info, sizeof (sdinfo->satadrv_id.ai_model)); swab(ap_info, ap_info, sizeof (sdinfo->satadrv_id.ai_model)); ap_info[sizeof (sdinfo->satadrv_id.ai_model)] = '\0'; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); info_len = strlen(ap_info) + 1; if (ioc.get_size) { if (ddi_copyout((void *)&info_len, ioc.buf, ioc.bufsiz, mode) != 0) { rv = EFAULT; break; } } else { if (ioc.bufsiz < info_len) { rv = EINVAL; break; } if (ddi_copyout((void *)ap_info, ioc.buf, ioc.bufsiz, mode) != 0) { rv = EFAULT; break; } } break; } case SATA_CFGA_GET_REVFIRMWARE_INFO: { uint32_t info_len; char ap_info[ sizeof (sdinfo->satadrv_id.ai_fw) + 1]; /* * This operation should return to cfgadm the * device firmware revision information string */ mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); /* only handle device connected to cport for now */ sata_device.satadev_addr.qual = SATA_ADDR_DCPORT; sdinfo = sata_get_device_info(sata_hba_inst, &sata_device); if (sdinfo == NULL) { mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); rv = EINVAL; break; } bcopy(sdinfo->satadrv_id.ai_fw, ap_info, sizeof (sdinfo->satadrv_id.ai_fw)); swab(ap_info, ap_info, sizeof (sdinfo->satadrv_id.ai_fw)); ap_info[sizeof (sdinfo->satadrv_id.ai_fw)] = '\0'; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); info_len = strlen(ap_info) + 1; if (ioc.get_size) { if (ddi_copyout((void *)&info_len, ioc.buf, ioc.bufsiz, mode) != 0) { rv = EFAULT; break; } } else { if (ioc.bufsiz < info_len) { rv = EINVAL; break; } if (ddi_copyout((void *)ap_info, ioc.buf, ioc.bufsiz, mode) != 0) { rv = EFAULT; break; } } break; } case SATA_CFGA_GET_SERIALNUMBER_INFO: { uint32_t info_len; char ap_info[ sizeof (sdinfo->satadrv_id.ai_drvser) + 1]; /* * This operation should return to cfgadm the * device serial number information string */ mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); /* only handle device connected to cport for now */ sata_device.satadev_addr.qual = SATA_ADDR_DCPORT; sdinfo = sata_get_device_info(sata_hba_inst, &sata_device); if (sdinfo == NULL) { mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); rv = EINVAL; break; } bcopy(sdinfo->satadrv_id.ai_drvser, ap_info, sizeof (sdinfo->satadrv_id.ai_drvser)); swab(ap_info, ap_info, sizeof (sdinfo->satadrv_id.ai_drvser)); ap_info[sizeof (sdinfo->satadrv_id.ai_drvser)] = '\0'; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)-> cport_mutex); info_len = strlen(ap_info) + 1; if (ioc.get_size) { if (ddi_copyout((void *)&info_len, ioc.buf, ioc.bufsiz, mode) != 0) { rv = EFAULT; break; } } else { if (ioc.bufsiz < info_len) { rv = EINVAL; break; } if (ddi_copyout((void *)ap_info, ioc.buf, ioc.bufsiz, mode) != 0) { rv = EFAULT; break; } } break; } default: rv = EINVAL; break; } /* End of DEVCTL_AP_CONTROL cmd switch */ break; } default: { /* * If we got here, we got an IOCTL that SATA HBA Framework * does not recognize. Pass ioctl to HBA driver, in case * it could process it. */ sata_hba_tran_t *sata_tran = sata_hba_inst->satahba_tran; dev_info_t *mydip = SATA_DIP(sata_hba_inst); SATADBG1(SATA_DBG_IOCTL_IF, sata_hba_inst, "IOCTL 0x%2x not supported in SATA framework, " "passthrough to HBA", cmd); if (sata_tran->sata_tran_ioctl == NULL) { rv = EINVAL; break; } rval = (*sata_tran->sata_tran_ioctl)(mydip, cmd, arg); if (rval != 0) { SATADBG1(SATA_DBG_IOCTL_IF, sata_hba_inst, "IOCTL 0x%2x failed in HBA", cmd); rv = rval; } break; } } /* End of main IOCTL switch */ if (dcp) { ndi_dc_freehdl(dcp); } mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); cportinfo->cport_event_flags &= ~SATA_APCTL_LOCK_PORT_BUSY; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, cport)->cport_mutex); return (rv); } /* ****************** SCSA required entry points *********************** */ /* * Implementation of scsi tran_tgt_init. * sata_scsi_tgt_init() initializes scsi_device structure * * If successful, DDI_SUCCESS is returned. * DDI_FAILURE is returned if addressed device does not exist */ static int sata_scsi_tgt_init(dev_info_t *hba_dip, dev_info_t *tgt_dip, scsi_hba_tran_t *hba_tran, struct scsi_device *sd) { #ifndef __lock_lint _NOTE(ARGUNUSED(hba_dip)) #endif sata_device_t sata_device; sata_drive_info_t *sdinfo; sata_hba_inst_t *sata_hba_inst; sata_hba_inst = (sata_hba_inst_t *)(hba_tran->tran_hba_private); /* Validate scsi device address */ if (sata_validate_scsi_address(sata_hba_inst, &sd->sd_address, &sata_device) != 0) return (DDI_FAILURE); mutex_enter(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); /* sata_device now contains a valid sata address */ sdinfo = sata_get_device_info(sata_hba_inst, &sata_device); if (sdinfo == NULL) { mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); return (DDI_FAILURE); } if (sata_device.satadev_type == SATA_DTYPE_ATAPICD) { mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); if (ndi_prop_update_string(DDI_DEV_T_NONE, tgt_dip, "variant", "atapi") != DDI_PROP_SUCCESS) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_scsi_tgt_init: variant atapi " "property could not be created")); return (DDI_FAILURE); } return (DDI_SUCCESS); } mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); return (DDI_SUCCESS); } /* * Implementation of scsi tran_tgt_probe. * Probe target, by calling default scsi routine scsi_hba_probe() */ static int sata_scsi_tgt_probe(struct scsi_device *sd, int (*callback)(void)) { sata_hba_inst_t *sata_hba_inst = (sata_hba_inst_t *)(sd->sd_address.a_hba_tran->tran_hba_private); int rval; rval = scsi_hba_probe(sd, callback); if (rval == SCSIPROBE_EXISTS) { /* * Set property "pm-capable" on the target device node, so that * the target driver will not try to fetch scsi cycle counters * before enabling device power-management. */ if ((ddi_prop_update_int(DDI_DEV_T_NONE, sd->sd_dev, "pm-capable", 1)) != DDI_PROP_SUCCESS) { sata_log(sata_hba_inst, CE_WARN, "device at port %d: will not be power-managed ", SCSI_TO_SATA_CPORT(sd->sd_address.a_target)); SATA_LOG_D((sata_hba_inst, CE_WARN, "failure updating pm-capable property")); } } return (rval); } /* * Implementation of scsi tran_tgt_free. * Release all resources allocated for scsi_device */ static void sata_scsi_tgt_free(dev_info_t *hba_dip, dev_info_t *tgt_dip, scsi_hba_tran_t *hba_tran, struct scsi_device *sd) { #ifndef __lock_lint _NOTE(ARGUNUSED(hba_dip)) #endif sata_device_t sata_device; sata_drive_info_t *sdinfo; sata_hba_inst_t *sata_hba_inst; sata_hba_inst = (sata_hba_inst_t *)(hba_tran->tran_hba_private); /* Validate scsi device address */ if (sata_validate_scsi_address(sata_hba_inst, &sd->sd_address, &sata_device) != 0) return; mutex_enter(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); /* sata_device now should contain a valid sata address */ sdinfo = sata_get_device_info(sata_hba_inst, &sata_device); if (sdinfo == NULL) { mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); return; } /* * We did not allocate any resources in sata_scsi_tgt_init() * other than property for ATAPI device, if any */ if (sata_device.satadev_type == SATA_DTYPE_ATAPICD) { mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); if (ndi_prop_remove(DDI_DEV_T_NONE, tgt_dip, "variant") != DDI_PROP_SUCCESS) SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_scsi_tgt_free: variant atapi " "property could not be removed")); } else { mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); } } /* * Implementation of scsi tran_init_pkt * Upon successful return, scsi pkt buffer has DMA resources allocated. * * It seems that we should always allocate pkt, even if the address is * for non-existing device - just use some default for dma_attr. * The reason is that there is no way to communicate this to a caller here. * Subsequent call to sata_scsi_start may fail appropriately. * Simply returning NULL does not seem to discourage a target driver... * * Returns a pointer to initialized scsi_pkt, or NULL otherwise. */ static struct scsi_pkt * sata_scsi_init_pkt(struct scsi_address *ap, struct scsi_pkt *pkt, struct buf *bp, int cmdlen, int statuslen, int tgtlen, int flags, int (*callback)(caddr_t), caddr_t arg) { sata_hba_inst_t *sata_hba_inst = (sata_hba_inst_t *)(ap->a_hba_tran->tran_hba_private); dev_info_t *dip = SATA_DIP(sata_hba_inst); sata_device_t sata_device; sata_drive_info_t *sdinfo; sata_pkt_txlate_t *spx; ddi_dma_attr_t cur_dma_attr; int rval; boolean_t new_pkt = TRUE; ASSERT(ap->a_hba_tran->tran_hba_dip == dip); /* * We need to translate the address, even if it could be * a bogus one, for a non-existing device */ sata_device.satadev_addr.qual = SCSI_TO_SATA_ADDR_QUAL(ap->a_target); sata_device.satadev_addr.cport = SCSI_TO_SATA_CPORT(ap->a_target); sata_device.satadev_addr.pmport = SCSI_TO_SATA_PMPORT(ap->a_target); sata_device.satadev_rev = SATA_DEVICE_REV; if (pkt == NULL) { /* * Have to allocate a brand new scsi packet. * We need to operate with auto request sense enabled. */ pkt = scsi_hba_pkt_alloc(dip, ap, cmdlen, MAX(statuslen, sizeof (struct scsi_arq_status)), tgtlen, sizeof (sata_pkt_txlate_t), callback, arg); if (pkt == NULL) return (NULL); /* Fill scsi packet structure */ pkt->pkt_comp = (void (*)())NULL; pkt->pkt_time = 0; pkt->pkt_resid = 0; pkt->pkt_statistics = 0; pkt->pkt_reason = 0; /* * pkt_hba_private will point to sata pkt txlate structure */ spx = (sata_pkt_txlate_t *)pkt->pkt_ha_private; bzero(spx, sizeof (sata_pkt_txlate_t)); spx->txlt_scsi_pkt = pkt; spx->txlt_sata_hba_inst = sata_hba_inst; /* Allocate sata_pkt */ spx->txlt_sata_pkt = sata_pkt_alloc(spx, callback); if (spx->txlt_sata_pkt == NULL) { /* Could not allocate sata pkt */ scsi_hba_pkt_free(ap, pkt); return (NULL); } /* Set sata address */ spx->txlt_sata_pkt->satapkt_device = sata_device; if ((bp == NULL) || (bp->b_bcount == 0)) return (pkt); spx->txlt_total_residue = bp->b_bcount; } else { new_pkt = FALSE; /* * Packet was preallocated/initialized by previous call */ spx = (sata_pkt_txlate_t *)pkt->pkt_ha_private; if ((bp == NULL) || (bp->b_bcount == 0)) { return (pkt); } ASSERT(spx->txlt_buf_dma_handle != NULL); /* Pkt is available already: spx->txlt_scsi_pkt == pkt; */ } spx->txlt_sata_pkt->satapkt_cmd.satacmd_bp = bp; /* * We use an adjusted version of the dma_attr, to account * for device addressing limitations. * sata_adjust_dma_attr() will handle sdinfo == NULL which may * happen when a device is not yet configured. */ mutex_enter(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); sdinfo = sata_get_device_info(spx->txlt_sata_hba_inst, &spx->txlt_sata_pkt->satapkt_device); /* NULL sdinfo may be passsed to sata_adjust_dma_attr() */ sata_adjust_dma_attr(sdinfo, SATA_DMA_ATTR(spx->txlt_sata_hba_inst), &cur_dma_attr); mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); /* * Allocate necessary DMA resources for the packet's buffer */ if ((rval = sata_dma_buf_setup(spx, flags, callback, arg, &cur_dma_attr)) != DDI_SUCCESS) { sata_pkt_free(spx); /* * If a DMA allocation request fails with * DDI_DMA_NOMAPPING, indicate the error by calling * bioerror(9F) with bp and an error code of EFAULT. * If a DMA allocation request fails with * DDI_DMA_TOOBIG, indicate the error by calling * bioerror(9F) with bp and an error code of EINVAL. */ switch (rval) { case DDI_DMA_NORESOURCES: bioerror(bp, 0); break; case DDI_DMA_NOMAPPING: case DDI_DMA_BADATTR: bioerror(bp, EFAULT); break; case DDI_DMA_TOOBIG: default: bioerror(bp, EINVAL); break; } if (new_pkt == TRUE) { sata_pkt_free(spx); scsi_hba_pkt_free(ap, pkt); } return (NULL); } /* Set number of bytes that are not yet accounted for */ pkt->pkt_resid = spx->txlt_total_residue; ASSERT(pkt->pkt_resid >= 0); return (pkt); } /* * Implementation of scsi tran_start. * Translate scsi cmd into sata operation and return status. * Supported scsi commands: * SCMD_INQUIRY * SCMD_TEST_UNIT_READY * SCMD_START_STOP * SCMD_READ_CAPACITY * SCMD_REQUEST_SENSE * SCMD_LOG_SENSE_G1 (unimplemented) * SCMD_LOG_SELECT_G1 (unimplemented) * SCMD_MODE_SENSE (specific pages) * SCMD_MODE_SENSE_G1 (specific pages) * SCMD_MODE_SELECT (specific pages) * SCMD_MODE_SELECT_G1 (specific pages) * SCMD_SYNCHRONIZE_CACHE * SCMD_SYNCHRONIZE_CACHE_G1 * SCMD_READ * SCMD_READ_G1 * SCMD_READ_G4 * SCMD_READ_G5 * SCMD_WRITE * SCMD_WRITE_G1 * SCMD_WRITE_G4 * SCMD_WRITE_G5 * SCMD_SEEK (noop) * * All other commands are rejected as unsupported. * * Returns: * TRAN_ACCEPT if command was executed successfully or accepted by HBA driver * for execution. * TRAN_BADPKT if cmd was directed to invalid address. * TRAN_FATAL_ERROR is command was rejected due to hardware error, including * unexpected removal of a device or some other unspecified error. * TRAN_BUSY if command could not be executed becasue HBA driver or SATA * framework was busy performing some other operation(s). * */ static int sata_scsi_start(struct scsi_address *ap, struct scsi_pkt *pkt) { sata_hba_inst_t *sata_hba_inst = (sata_hba_inst_t *)(ap->a_hba_tran->tran_hba_private); sata_pkt_txlate_t *spx = (sata_pkt_txlate_t *)pkt->pkt_ha_private; sata_drive_info_t *sdinfo; struct buf *bp; int cport; int rval; SATADBG1(SATA_DBG_SCSI_IF, sata_hba_inst, "sata_scsi_start: cmd 0x%02x\n", pkt->pkt_cdbp[0]); ASSERT(spx != NULL && spx->txlt_scsi_pkt == pkt && spx->txlt_sata_pkt != NULL); /* * Mutex-protected section below is just to identify device type * and switch to ATAPI processing, if necessary */ cport = SCSI_TO_SATA_CPORT(ap->a_target); mutex_enter(&(SATA_CPORT_MUTEX(sata_hba_inst, cport))); sdinfo = sata_get_device_info(sata_hba_inst, &spx->txlt_sata_pkt->satapkt_device); if (sdinfo == NULL) { mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, cport))); spx->txlt_scsi_pkt->pkt_reason = CMD_DEV_GONE; return (TRAN_FATAL_ERROR); } if (sdinfo->satadrv_type == SATA_DTYPE_ATAPICD) { mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, cport))); rval = sata_txlt_atapi(spx); SATADBG1(SATA_DBG_SCSI_IF, sata_hba_inst, "sata_scsi_start atapi: rval %d\n", rval); return (rval); } mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, cport))); /* ATA Disk commands processing starts here */ bp = spx->txlt_sata_pkt->satapkt_cmd.satacmd_bp; switch (pkt->pkt_cdbp[0]) { case SCMD_INQUIRY: /* Mapped to identify device */ if (bp != NULL && (bp->b_flags & (B_PHYS | B_PAGEIO))) bp_mapin(bp); rval = sata_txlt_inquiry(spx); break; case SCMD_TEST_UNIT_READY: /* * SAT "SATA to ATA Translation" doc specifies translation * to ATA CHECK POWER MODE. */ rval = sata_txlt_test_unit_ready(spx); break; case SCMD_START_STOP: /* Mapping depends on the command */ rval = sata_txlt_start_stop_unit(spx); break; case SCMD_READ_CAPACITY: if (bp != NULL && (bp->b_flags & (B_PHYS | B_PAGEIO))) bp_mapin(bp); rval = sata_txlt_read_capacity(spx); break; case SCMD_REQUEST_SENSE: /* * Always No Sense, since we force ARQ */ if (bp != NULL && (bp->b_flags & (B_PHYS | B_PAGEIO))) bp_mapin(bp); rval = sata_txlt_request_sense(spx); break; case SCMD_LOG_SENSE_G1: if (bp != NULL && (bp->b_flags & (B_PHYS | B_PAGEIO))) bp_mapin(bp); rval = sata_txlt_log_sense(spx); break; case SCMD_LOG_SELECT_G1: if (bp != NULL && (bp->b_flags & (B_PHYS | B_PAGEIO))) bp_mapin(bp); rval = sata_txlt_log_select(spx); break; case SCMD_MODE_SENSE: case SCMD_MODE_SENSE_G1: if (bp != NULL && (bp->b_flags & (B_PHYS | B_PAGEIO))) bp_mapin(bp); rval = sata_txlt_mode_sense(spx); break; case SCMD_MODE_SELECT: case SCMD_MODE_SELECT_G1: if (bp != NULL && (bp->b_flags & (B_PHYS | B_PAGEIO))) bp_mapin(bp); rval = sata_txlt_mode_select(spx); break; case SCMD_SYNCHRONIZE_CACHE: case SCMD_SYNCHRONIZE_CACHE_G1: rval = sata_txlt_synchronize_cache(spx); break; case SCMD_READ: case SCMD_READ_G1: case SCMD_READ_G4: case SCMD_READ_G5: rval = sata_txlt_read(spx); break; case SCMD_WRITE: case SCMD_WRITE_G1: case SCMD_WRITE_G4: case SCMD_WRITE_G5: rval = sata_txlt_write(spx); break; case SCMD_SEEK: rval = sata_txlt_nodata_cmd_immediate(spx); break; /* Other cases will be filed later */ /* postponed until phase 2 of the development */ default: rval = sata_txlt_invalid_command(spx); break; } SATADBG1(SATA_DBG_SCSI_IF, sata_hba_inst, "sata_scsi_start: rval %d\n", rval); return (rval); } /* * Implementation of scsi tran_abort. * Abort specific pkt or all packets. * * Returns 1 if one or more packets were aborted, returns 0 otherwise * * May be called from an interrupt level. */ static int sata_scsi_abort(struct scsi_address *ap, struct scsi_pkt *scsi_pkt) { sata_hba_inst_t *sata_hba_inst = (sata_hba_inst_t *)(ap->a_hba_tran->tran_hba_private); sata_device_t sata_device; sata_pkt_t *sata_pkt; SATADBG2(SATA_DBG_SCSI_IF, sata_hba_inst, "sata_scsi_abort: %s at target: 0x%x\n", scsi_pkt == NULL ? "all packets" : "one pkt", ap->a_target); /* Validate address */ if (sata_validate_scsi_address(sata_hba_inst, ap, &sata_device) != 0) /* Invalid address */ return (0); mutex_enter(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); if (sata_get_device_info(sata_hba_inst, &sata_device) == NULL) { /* invalid address */ mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); return (0); } if (scsi_pkt == NULL) { /* * Abort all packets. * Although we do not have specific packet, we still need * dummy packet structure to pass device address to HBA. * Allocate one, without sleeping. Fail if pkt cannot be * allocated. */ sata_pkt = kmem_zalloc(sizeof (sata_pkt_t), KM_NOSLEEP); if (sata_pkt == NULL) { mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_pkt_abort: " "could not allocate sata_pkt")); return (0); } sata_pkt->satapkt_rev = SATA_PKT_REV; sata_pkt->satapkt_device = sata_device; sata_pkt->satapkt_device.satadev_rev = SATA_DEVICE_REV; } else { if (scsi_pkt->pkt_ha_private == NULL) { mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); return (0); /* Bad scsi pkt */ } /* extract pointer to sata pkt */ sata_pkt = ((sata_pkt_txlate_t *)scsi_pkt->pkt_ha_private)-> txlt_sata_pkt; } mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); /* Send abort request to HBA */ if ((*SATA_ABORT_FUNC(sata_hba_inst)) (SATA_DIP(sata_hba_inst), sata_pkt, scsi_pkt == NULL ? SATA_ABORT_ALL_PACKETS : SATA_ABORT_PACKET) == SATA_SUCCESS) { if (scsi_pkt == NULL) kmem_free(sata_pkt, sizeof (sata_pkt_t)); /* Success */ return (1); } /* Else, something did not go right */ if (scsi_pkt == NULL) kmem_free(sata_pkt, sizeof (sata_pkt_t)); /* Failure */ return (0); } /* * Implementation os scsi tran_reset. * RESET_ALL request is translated into port reset. * RESET_TARGET requests is translated into a device reset, * RESET_LUN request is accepted only for LUN 0 and translated into * device reset. * The target reset should cause all HBA active and queued packets to * be terminated and returned with pkt reason SATA_PKT_RESET prior to * the return. HBA should report reset event for the device. * * Returns 1 upon success, 0 upon failure. */ static int sata_scsi_reset(struct scsi_address *ap, int level) { sata_hba_inst_t *sata_hba_inst = (sata_hba_inst_t *)(ap->a_hba_tran->tran_hba_private); sata_device_t sata_device; int val; SATADBG2(SATA_DBG_SCSI_IF, sata_hba_inst, "sata_scsi_reset: level %d target: 0x%x\n", level, ap->a_target); /* Validate address */ val = sata_validate_scsi_address(sata_hba_inst, ap, &sata_device); if (val == -1) /* Invalid address */ return (0); mutex_enter(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); if (sata_get_device_info(sata_hba_inst, &sata_device) == NULL) { /* invalid address */ mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); return (0); } mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); if (level == RESET_ALL) { /* port reset - cport only */ sata_device.satadev_addr.qual = SATA_ADDR_CPORT; if ((*SATA_RESET_DPORT_FUNC(sata_hba_inst)) (SATA_DIP(sata_hba_inst), &sata_device) == SATA_SUCCESS) return (1); else return (0); } else if (val == 0 && (level == RESET_TARGET || level == RESET_LUN)) { /* reset device (device attached) */ if ((*SATA_RESET_DPORT_FUNC(sata_hba_inst)) (SATA_DIP(sata_hba_inst), &sata_device) == SATA_SUCCESS) return (1); else return (0); } return (0); } /* * Implementation of scsi tran_getcap (get transport/device capabilities). * Supported capabilities: * auto-rqsense (always supported) * tagged-qing (supported if HBA supports it) * dma_max * interconnect-type (INTERCONNECT_SATA) * * Request for other capabilities is rejected as unsupported. * * Returns supported capability value, or -1 if capability is unsuppported or * the address is invalid (no device). */ static int sata_scsi_getcap(struct scsi_address *ap, char *cap, int whom) { sata_hba_inst_t *sata_hba_inst = (sata_hba_inst_t *)(ap->a_hba_tran->tran_hba_private); sata_device_t sata_device; sata_drive_info_t *sdinfo; ddi_dma_attr_t adj_dma_attr; int rval; SATADBG2(SATA_DBG_SCSI_IF, sata_hba_inst, "sata_scsi_getcap: target: 0x%x, cap: %s\n", ap->a_target, cap); /* * We want to process the capabilities on per port granularity. * So, we are specifically restricting ourselves to whom != 0 * to exclude the controller wide handling. */ if (cap == NULL || whom == 0) return (-1); if (sata_validate_scsi_address(sata_hba_inst, ap, &sata_device) != 0) { /* Invalid address */ return (-1); } mutex_enter(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); if ((sdinfo = sata_get_device_info(sata_hba_inst, &sata_device)) == NULL) { /* invalid address */ mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); return (0); } switch (scsi_hba_lookup_capstr(cap)) { case SCSI_CAP_ARQ: rval = 1; /* ARQ supported, turned on */ break; case SCSI_CAP_SECTOR_SIZE: if (sdinfo->satadrv_type == SATA_DTYPE_ATADISK) rval = SATA_DISK_SECTOR_SIZE; /* fixed size */ else if (sdinfo->satadrv_type == SATA_DTYPE_ATAPICD) rval = SATA_ATAPI_SECTOR_SIZE; else rval = -1; break; case SCSI_CAP_TAGGED_QING: /* * It is enough if the controller supports queuing, regardless * of the device. NCQ support is an internal implementation * feature used between HBA and the device. */ if (SATA_QDEPTH(sata_hba_inst) > 1) rval = 1; /* Queuing supported */ else rval = -1; /* Queuing not supported */ break; case SCSI_CAP_DMA_MAX: sata_adjust_dma_attr(sdinfo, SATA_DMA_ATTR(sata_hba_inst), &adj_dma_attr); rval = (int)adj_dma_attr.dma_attr_maxxfer; /* We rely on the fact that dma_attr_maxxfer < 0x80000000 */ break; case SCSI_CAP_INTERCONNECT_TYPE: rval = INTERCONNECT_SATA; /* SATA interconnect type */ break; default: rval = -1; break; } mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); return (rval); } /* * Implementation of scsi tran_setcap * * All supported capabilities are fixed/unchangeable. * Returns 0 for all supported capabilities and valid device, -1 otherwise. */ static int sata_scsi_setcap(struct scsi_address *ap, char *cap, int value, int whom) { #ifndef __lock_lint _NOTE(ARGUNUSED(value)) #endif sata_hba_inst_t *sata_hba_inst = (sata_hba_inst_t *)(ap->a_hba_tran->tran_hba_private); sata_device_t sata_device; int rval; SATADBG2(SATA_DBG_SCSI_IF, sata_hba_inst, "sata_scsi_setcap: target: 0x%x, cap: %s\n", ap->a_target, cap); /* * We want to process the capabilities on per port granularity. * So, we are specifically restricting ourselves to whom != 0 * to exclude the controller wide handling. */ if (cap == NULL || whom == 0) { return (-1); } if (sata_validate_scsi_address(sata_hba_inst, ap, &sata_device) != 0) { /* Invalid address */ return (-1); } mutex_enter(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); if (sata_get_device_info(sata_hba_inst, &sata_device) == NULL) { /* invalid address */ mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); return (0); } mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device.satadev_addr.cport))); switch (scsi_hba_lookup_capstr(cap)) { case SCSI_CAP_ARQ: case SCSI_CAP_SECTOR_SIZE: case SCSI_CAP_TAGGED_QING: case SCSI_CAP_DMA_MAX: case SCSI_CAP_INTERCONNECT_TYPE: rval = 0; /* Capability cannot be changed */ break; default: rval = -1; break; } return (rval); } /* * Implementations of scsi tran_destroy_pkt. * Free resources allocated by sata_scsi_init_pkt() */ static void sata_scsi_destroy_pkt(struct scsi_address *ap, struct scsi_pkt *pkt) { sata_pkt_txlate_t *spx; ASSERT(pkt != NULL); spx = (sata_pkt_txlate_t *)pkt->pkt_ha_private; if (spx->txlt_buf_dma_handle != NULL) { /* * Free DMA resources - cookies and handles */ ASSERT(spx->txlt_dma_cookie_list != NULL); (void) kmem_free(spx->txlt_dma_cookie_list, spx->txlt_dma_cookie_list_len * sizeof (ddi_dma_cookie_t)); (void) ddi_dma_unbind_handle(spx->txlt_buf_dma_handle); (void) ddi_dma_free_handle(&spx->txlt_buf_dma_handle); } spx->txlt_sata_pkt->satapkt_cmd.satacmd_bp = NULL; sata_pkt_free(spx); scsi_hba_pkt_free(ap, pkt); } /* * Implementation of scsi tran_dmafree. * Free DMA resources allocated by sata_scsi_init_pkt() */ static void sata_scsi_dmafree(struct scsi_address *ap, struct scsi_pkt *pkt) { #ifndef __lock_lint _NOTE(ARGUNUSED(ap)) #endif sata_pkt_txlate_t *spx; ASSERT(pkt != NULL); spx = (sata_pkt_txlate_t *)pkt->pkt_ha_private; if (spx->txlt_buf_dma_handle != NULL) { /* * Free DMA resources - cookies and handles */ ASSERT(spx->txlt_dma_cookie_list != NULL); (void) kmem_free(spx->txlt_dma_cookie_list, spx->txlt_dma_cookie_list_len * sizeof (ddi_dma_cookie_t)); (void) ddi_dma_unbind_handle(spx->txlt_buf_dma_handle); (void) ddi_dma_free_handle(&spx->txlt_buf_dma_handle); } } /* * Implementation of scsi tran_sync_pkt. * * The assumption below is that pkt is unique - there is no need to check ap */ static void sata_scsi_sync_pkt(struct scsi_address *ap, struct scsi_pkt *pkt) { #ifndef __lock_lint _NOTE(ARGUNUSED(ap)) #endif int rval; sata_pkt_txlate_t *spx = (sata_pkt_txlate_t *)pkt->pkt_ha_private; if (spx->txlt_buf_dma_handle != NULL) { if (spx->txlt_sata_pkt != NULL && spx->txlt_sata_pkt->satapkt_cmd.satacmd_flags. sata_data_direction != SATA_DIR_NODATA_XFER) { rval = ddi_dma_sync(spx->txlt_buf_dma_handle, 0, 0, (spx->txlt_sata_pkt->satapkt_cmd. satacmd_flags.sata_data_direction & SATA_DIR_WRITE) ? DDI_DMA_SYNC_FORDEV : DDI_DMA_SYNC_FORCPU); if (rval == DDI_SUCCESS) { SATA_LOG_D((spx->txlt_sata_hba_inst, CE_WARN, "sata_scsi_sync_pkt: sync pkt failed")); } } } } /* ******************* SATA - SCSI Translation functions **************** */ /* * SCSI to SATA pkt and command translation and SATA to SCSI status/error * translation. */ /* * Checks if a device exists and can be access and translates common * scsi_pkt data to sata_pkt data. * * Returns TRAN_ACCEPT if device exists and sata_pkt was set-up. * Returns other TRAN_XXXXX values when error occured. * * This function should be called with port mutex held. */ static int sata_txlt_generic_pkt_info(sata_pkt_txlate_t *spx) { sata_drive_info_t *sdinfo; sata_device_t sata_device; const struct sata_cmd_flags sata_initial_cmd_flags = { SATA_DIR_NODATA_XFER, /* all other values to 0/FALSE */ }; /* Validate address */ switch (sata_validate_scsi_address(spx->txlt_sata_hba_inst, &spx->txlt_scsi_pkt->pkt_address, &sata_device)) { case -1: /* Invalid address or invalid device type */ return (TRAN_BADPKT); case 1: /* valid address but no device - it has disappeared ? */ spx->txlt_scsi_pkt->pkt_reason = CMD_DEV_GONE; return (TRAN_FATAL_ERROR); default: /* all OK */ break; } sdinfo = sata_get_device_info(spx->txlt_sata_hba_inst, &spx->txlt_sata_pkt->satapkt_device); /* * If device is in reset condition, reject the packet with * TRAN_BUSY */ if (sdinfo->satadrv_event_flags & (SATA_EVNT_DEVICE_RESET | SATA_EVNT_INPROC_DEVICE_RESET)) { spx->txlt_scsi_pkt->pkt_reason = CMD_INCOMPLETE; SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "sata_scsi_start: rejecting command because " "of device reset state\n", NULL); return (TRAN_BUSY); } /* * Fix the dev_type in the sata_pkt->satapkt_device. It was not set by * sata_scsi_pkt_init() because pkt init had to work also with * non-existing devices. * Now we know that the packet was set-up for a real device, so its * type is known. */ spx->txlt_sata_pkt->satapkt_device.satadev_type = sdinfo->satadrv_type; spx->txlt_sata_pkt->satapkt_cmd.satacmd_flags = sata_initial_cmd_flags; spx->txlt_scsi_pkt->pkt_reason = CMD_CMPLT; if ((spx->txlt_scsi_pkt->pkt_flags & FLAG_NOINTR) != 0) { /* Synchronous execution */ spx->txlt_sata_pkt->satapkt_op_mode = SATA_OPMODE_SYNCH | SATA_OPMODE_POLLING; } else { /* Asynchronous execution */ spx->txlt_sata_pkt->satapkt_op_mode = SATA_OPMODE_ASYNCH | SATA_OPMODE_INTERRUPTS; } /* Convert queuing information */ if (spx->txlt_scsi_pkt->pkt_flags & FLAG_STAG) spx->txlt_sata_pkt->satapkt_cmd.satacmd_flags.sata_queue_stag = B_TRUE; else if (spx->txlt_scsi_pkt->pkt_flags & (FLAG_OTAG | FLAG_HTAG | FLAG_HEAD)) spx->txlt_sata_pkt->satapkt_cmd.satacmd_flags.sata_queue_otag = B_TRUE; /* Always limit pkt time */ if (spx->txlt_scsi_pkt->pkt_time == 0) spx->txlt_sata_pkt->satapkt_time = sata_default_pkt_time; else /* Pass on scsi_pkt time */ spx->txlt_sata_pkt->satapkt_time = spx->txlt_scsi_pkt->pkt_time; return (TRAN_ACCEPT); } /* * Translate ATA(ATAPI) Identify (Packet) Device data to SCSI Inquiry data. * SATA Identify Device data has to be valid in sata_rive_info. * Buffer has to accomodate the inquiry length (36 bytes). * * This function should be called with a port mutex held. */ static void sata_identdev_to_inquiry(sata_hba_inst_t *sata_hba_inst, sata_drive_info_t *sdinfo, uint8_t *buf) { struct scsi_inquiry *inq = (struct scsi_inquiry *)buf; struct sata_id *sid = &sdinfo->satadrv_id; /* Start with a nice clean slate */ bzero((void *)inq, sizeof (struct scsi_inquiry)); /* Rely on the dev_type for setting paripheral qualifier */ /* Does DTYPE_RODIRECT apply to CD/DVD R/W devices ? */ inq->inq_dtype = sdinfo->satadrv_type == SATA_DTYPE_ATADISK ? DTYPE_DIRECT : DTYPE_RODIRECT; inq->inq_rmb = sid->ai_config & SATA_REM_MEDIA ? 1 : 0; inq->inq_qual = 0; /* Device type qualifier (obsolete in SCSI3? */ inq->inq_iso = 0; /* ISO version */ inq->inq_ecma = 0; /* ECMA version */ inq->inq_ansi = 3; /* ANSI version - SCSI 3 */ inq->inq_aenc = 0; /* Async event notification cap. */ inq->inq_trmiop = 0; /* Supports TERMINATE I/O PROC msg ??? */ inq->inq_normaca = 0; /* setting NACA bit supported - NO */ inq->inq_rdf = RDF_SCSI2; /* Response data format- SPC-3 */ inq->inq_len = 31; /* Additional length */ inq->inq_dualp = 0; /* dual port device - NO */ inq->inq_reladdr = 0; /* Supports relative addressing - NO */ inq->inq_sync = 0; /* Supports synchronous data xfers - NO */ inq->inq_linked = 0; /* Supports linked commands - NO */ /* * Queuing support - controller has to * support some sort of command queuing. */ if (SATA_QDEPTH(sata_hba_inst) > 1) inq->inq_cmdque = 1; /* Supports command queueing - YES */ else inq->inq_cmdque = 0; /* Supports command queueing - NO */ inq->inq_sftre = 0; /* Supports Soft Reset option - NO ??? */ inq->inq_wbus32 = 0; /* Supports 32 bit wide data xfers - NO */ inq->inq_wbus16 = 0; /* Supports 16 bit wide data xfers - NO */ #ifdef _LITTLE_ENDIAN /* Swap text fields to match SCSI format */ bcopy("ATA ", inq->inq_vid, 8); /* Vendor ID */ swab(sid->ai_model, inq->inq_pid, 16); /* Product ID */ if (strncmp(&sid->ai_fw[4], " ", 4) == 0) swab(sid->ai_fw, inq->inq_revision, 4); /* Revision level */ else swab(&sid->ai_fw[4], inq->inq_revision, 4); /* Rev. level */ #else bcopy(sid->ai_model, inq->inq_vid, 8); /* Vendor ID */ bcopy(&sid->ai_model[8], inq->inq_pid, 16); /* Product ID */ if (strncmp(&sid->ai_fw[4], " ", 4) == 0) bcopy(sid->ai_fw, inq->inq_revision, 4); /* Revision level */ else bcopy(&sid->ai_fw[4], inq->inq_revision, 4); /* Rev. level */ #endif } /* * Scsi response set up for invalid command (command not supported) * * Returns TRAN_ACCEPT and appropriate values in scsi_pkt fields. */ static int sata_txlt_invalid_command(sata_pkt_txlate_t *spx) { struct scsi_pkt *scsipkt = spx->txlt_scsi_pkt; struct scsi_extended_sense *sense; scsipkt->pkt_reason = CMD_CMPLT; scsipkt->pkt_state = STATE_GOT_BUS | STATE_GOT_TARGET | STATE_SENT_CMD | STATE_GOT_STATUS; *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); sense->es_key = KEY_ILLEGAL_REQUEST; sense->es_add_code = SD_SCSI_INVALID_COMMAND_CODE; SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "Scsi_pkt completion reason %x\n", scsipkt->pkt_reason); if ((scsipkt->pkt_flags & FLAG_NOINTR) == 0 && scsipkt->pkt_comp != NULL) /* scsi callback required */ (*scsipkt->pkt_comp)(scsipkt); return (TRAN_ACCEPT); } /* * Scsi response setup for * emulated non-data command that requires no action/return data * * Returns TRAN_ACCEPT and appropriate values in scsi_pkt fields. */ static int sata_txlt_nodata_cmd_immediate(sata_pkt_txlate_t *spx) { int rval; mutex_enter(&(SATA_TXLT_CPORT_MUTEX(spx))); if ((rval = sata_txlt_generic_pkt_info(spx)) != TRAN_ACCEPT) { mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); return (rval); } mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); spx->txlt_scsi_pkt->pkt_state = STATE_GOT_BUS | STATE_GOT_TARGET | STATE_SENT_CMD | STATE_GOT_STATUS; spx->txlt_scsi_pkt->pkt_reason = CMD_CMPLT; *(spx->txlt_scsi_pkt->pkt_scbp) = STATUS_GOOD; SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "Scsi_pkt completion reason %x\n", spx->txlt_scsi_pkt->pkt_reason); if ((spx->txlt_scsi_pkt->pkt_flags & FLAG_NOINTR) == 0 && spx->txlt_scsi_pkt->pkt_comp != NULL) /* scsi callback required */ (*spx->txlt_scsi_pkt->pkt_comp)(spx->txlt_scsi_pkt); return (TRAN_ACCEPT); } /* * SATA translate command: Inquiry / Identify Device * Use cached Identify Device data for now, rather then issuing actual * Device Identify cmd request. If device is detached and re-attached, * asynchromous event processing should fetch and refresh Identify Device * data. * Two VPD pages are supported now: * Vital Product Data page * Unit Serial Number page * * Returns TRAN_ACCEPT and appropriate values in scsi_pkt fields. */ #define EVPD 1 /* Extended Vital Product Data flag */ #define CMDDT 2 /* Command Support Data - Obsolete */ #define INQUIRY_SUP_VPD_PAGE 0 /* Supported VDP Pages Page COde */ #define INQUIRY_USN_PAGE 0x80 /* Unit Serial Number Page Code */ #define INQUIRY_DEV_IDENTIFICATION_PAGE 0x83 /* Not needed yet */ static int sata_txlt_inquiry(sata_pkt_txlate_t *spx) { struct scsi_pkt *scsipkt = spx->txlt_scsi_pkt; struct buf *bp = spx->txlt_sata_pkt->satapkt_cmd.satacmd_bp; sata_drive_info_t *sdinfo; struct scsi_extended_sense *sense; int count; uint8_t *p; int i, j; uint8_t page_buf[0xff]; /* Max length */ int rval; mutex_enter(&(SATA_TXLT_CPORT_MUTEX(spx))); if ((rval = sata_txlt_generic_pkt_info(spx)) != TRAN_ACCEPT) { mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); return (rval); } sdinfo = sata_get_device_info(spx->txlt_sata_hba_inst, &spx->txlt_sata_pkt->satapkt_device); ASSERT(sdinfo != NULL); scsipkt->pkt_reason = CMD_CMPLT; scsipkt->pkt_state = STATE_GOT_BUS | STATE_GOT_TARGET | STATE_SENT_CMD | STATE_GOT_STATUS; /* Reject not supported request */ if (scsipkt->pkt_cdbp[1] & CMDDT) { /* No support for this bit */ *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); sense->es_key = KEY_ILLEGAL_REQUEST; sense->es_add_code = SD_SCSI_INVALID_FIELD_IN_CDB; goto done; } /* Valid Inquiry request */ *scsipkt->pkt_scbp = STATUS_GOOD; if (bp != NULL && bp->b_un.b_addr && bp->b_bcount) { if (!(scsipkt->pkt_cdbp[1] & EVPD)) { /* Standard Inquiry Data request */ struct scsi_inquiry inq; unsigned int bufsize; sata_identdev_to_inquiry(spx->txlt_sata_hba_inst, sdinfo, (uint8_t *)&inq); /* Copy no more than requested */ count = MIN(bp->b_bcount, sizeof (struct scsi_inquiry)); bufsize = scsipkt->pkt_cdbp[4]; bufsize |= scsipkt->pkt_cdbp[3] << 8; count = MIN(count, bufsize); bcopy(&inq, bp->b_un.b_addr, count); scsipkt->pkt_state |= STATE_XFERRED_DATA; scsipkt->pkt_resid = scsipkt->pkt_cdbp[4] > count ? bufsize - count : 0; } else { /* * peripheral_qualifier = 0; * * We are dealing only with HD and will be * dealing with CD/DVD devices soon */ uint8_t peripheral_device_type = sdinfo->satadrv_type == SATA_DTYPE_ATADISK ? DTYPE_DIRECT : DTYPE_RODIRECT; switch ((uint_t)scsipkt->pkt_cdbp[2]) { case INQUIRY_SUP_VPD_PAGE: /* * Request for suported Vital Product Data * pages - assuming only 2 page codes * supported */ page_buf[0] = peripheral_device_type; page_buf[1] = INQUIRY_SUP_VPD_PAGE; page_buf[2] = 0; page_buf[3] = 2; /* page length */ page_buf[4] = INQUIRY_SUP_VPD_PAGE; page_buf[5] = INQUIRY_USN_PAGE; /* Copy no more than requested */ count = MIN(bp->b_bcount, 6); bcopy(page_buf, bp->b_un.b_addr, count); break; case INQUIRY_USN_PAGE: /* * Request for Unit Serial Number page */ page_buf[0] = peripheral_device_type; page_buf[1] = INQUIRY_USN_PAGE; page_buf[2] = 0; page_buf[3] = 20; /* remaining page length */ p = (uint8_t *)(sdinfo->satadrv_id.ai_drvser); #ifdef _LITTLE_ENDIAN swab(p, &page_buf[4], 20); #else bcopy(p, &page_buf[4], 20); #endif for (i = 0; i < 20; i++) { if (page_buf[4 + i] == '\0' || page_buf[4 + i] == '\040') { break; } } /* * 'i' contains string length. * * Least significant character of the serial * number shall appear as the last byte, * according to SBC-3 spec. */ p = &page_buf[20 + 4 - 1]; for (j = i; j > 0; j--, p--) { *p = *(p - 20 + i); } p = &page_buf[4]; for (j = 20 - i; j > 0; j--) { *p++ = '\040'; } count = MIN(bp->b_bcount, 24); bcopy(page_buf, bp->b_un.b_addr, count); break; case INQUIRY_DEV_IDENTIFICATION_PAGE: /* * We may want to implement this page, when * identifiers are common for SATA devices * But not now. */ /*FALLTHRU*/ default: /* Request for unsupported VPD page */ *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); sense->es_key = KEY_ILLEGAL_REQUEST; sense->es_add_code = SD_SCSI_INVALID_FIELD_IN_CDB; goto done; } } scsipkt->pkt_state |= STATE_XFERRED_DATA; scsipkt->pkt_resid = scsipkt->pkt_cdbp[4] > count ? scsipkt->pkt_cdbp[4] - count : 0; } done: mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "Scsi_pkt completion reason %x\n", scsipkt->pkt_reason); if ((scsipkt->pkt_flags & FLAG_NOINTR) == 0 && scsipkt->pkt_comp != NULL) /* scsi callback required */ (*scsipkt->pkt_comp)(scsipkt); return (TRAN_ACCEPT); } /* * SATA translate command: Request Sense * emulated command (ATA version so far, no ATAPI) * Always NO SENSE, because any sense data should be reported by ARQ sense. * * Returns TRAN_ACCEPT and appropriate values in scsi_pkt fields. */ static int sata_txlt_request_sense(sata_pkt_txlate_t *spx) { struct scsi_pkt *scsipkt = spx->txlt_scsi_pkt; struct scsi_extended_sense sense; struct buf *bp = spx->txlt_sata_pkt->satapkt_cmd.satacmd_bp; int rval; mutex_enter(&(SATA_TXLT_CPORT_MUTEX(spx))); if ((rval = sata_txlt_generic_pkt_info(spx)) != TRAN_ACCEPT) { mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); return (rval); } mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); scsipkt->pkt_reason = CMD_CMPLT; scsipkt->pkt_state = STATE_GOT_BUS | STATE_GOT_TARGET | STATE_SENT_CMD | STATE_GOT_STATUS; *scsipkt->pkt_scbp = STATUS_GOOD; if (bp != NULL && bp->b_un.b_addr && bp->b_bcount) { int count = MIN(bp->b_bcount, sizeof (struct scsi_extended_sense)); bzero(&sense, sizeof (struct scsi_extended_sense)); sense.es_valid = 0; /* Valid LBA */ sense.es_class = 7; /* Response code 0x70 - current err */ sense.es_key = KEY_NO_SENSE; sense.es_add_len = 6; /* Additional length */ /* Copy no more than requested */ bcopy(&sense, bp->b_un.b_addr, count); scsipkt->pkt_state |= STATE_XFERRED_DATA; scsipkt->pkt_resid = 0; } SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "Scsi_pkt completion reason %x\n", scsipkt->pkt_reason); if ((scsipkt->pkt_flags & FLAG_NOINTR) == 0 && scsipkt->pkt_comp != NULL) /* scsi callback required */ (*scsipkt->pkt_comp)(scsipkt); return (TRAN_ACCEPT); } /* * SATA translate command: Test Unit Ready * At the moment this is an emulated command (ATA version so far, no ATAPI). * May be translated into Check Power Mode command in the future * * Returns TRAN_ACCEPT and appropriate values in scsi_pkt fields. */ static int sata_txlt_test_unit_ready(sata_pkt_txlate_t *spx) { struct scsi_pkt *scsipkt = spx->txlt_scsi_pkt; struct scsi_extended_sense *sense; int power_state; int rval; mutex_enter(&(SATA_TXLT_CPORT_MUTEX(spx))); if ((rval = sata_txlt_generic_pkt_info(spx)) != TRAN_ACCEPT) { mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); return (rval); } mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); /* At this moment, emulate it rather than execute anything */ power_state = SATA_PWRMODE_ACTIVE; scsipkt->pkt_reason = CMD_CMPLT; scsipkt->pkt_state = STATE_GOT_BUS | STATE_GOT_TARGET | STATE_SENT_CMD | STATE_GOT_STATUS; switch (power_state) { case SATA_PWRMODE_ACTIVE: case SATA_PWRMODE_IDLE: *scsipkt->pkt_scbp = STATUS_GOOD; break; default: /* PWR mode standby */ *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); sense->es_key = KEY_NOT_READY; sense->es_add_code = SD_SCSI_LU_NOT_READY; break; } SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "Scsi_pkt completion reason %x\n", scsipkt->pkt_reason); if ((scsipkt->pkt_flags & FLAG_NOINTR) == 0 && scsipkt->pkt_comp != NULL) /* scsi callback required */ (*scsipkt->pkt_comp)(scsipkt); return (TRAN_ACCEPT); } /* * SATA translate command: Start Stop Unit * Translation depends on a command: * Start Unit translated into Idle Immediate * Stop Unit translated into Standby Immediate * Unload Media / NOT SUPPORTED YET * Load Media / NOT SUPPROTED YET * Power condition bits are ignored, so is Immediate bit * Requesting synchronous execution. * * Returns TRAN_ACCEPT or code returned by sata_hba_start() and * appropriate values in scsi_pkt fields. */ static int sata_txlt_start_stop_unit(sata_pkt_txlate_t *spx) { struct scsi_pkt *scsipkt = spx->txlt_scsi_pkt; sata_cmd_t *scmd = &spx->txlt_sata_pkt->satapkt_cmd; struct scsi_extended_sense *sense; sata_hba_inst_t *shi = SATA_TXLT_HBA_INST(spx); int cport = SATA_TXLT_CPORT(spx); int rval; int synch; SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "sata_txlt_start_stop_unit: %d\n", scsipkt->pkt_scbp[4] & 1); mutex_enter(&SATA_CPORT_MUTEX(shi, cport)); if ((rval = sata_txlt_generic_pkt_info(spx)) != TRAN_ACCEPT) { mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); return (rval); } if (scsipkt->pkt_cdbp[4] & 2) { /* Load/Unload Media - invalid request */ *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); sense->es_key = KEY_ILLEGAL_REQUEST; sense->es_add_code = SD_SCSI_INVALID_FIELD_IN_CDB; mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "Scsi_pkt completion reason %x\n", scsipkt->pkt_reason); if ((scsipkt->pkt_flags & FLAG_NOINTR) == 0 && scsipkt->pkt_comp != NULL) /* scsi callback required */ (*scsipkt->pkt_comp)(scsipkt); return (TRAN_ACCEPT); } scmd->satacmd_addr_type = 0; scmd->satacmd_sec_count_lsb = 0; scmd->satacmd_lba_low_lsb = 0; scmd->satacmd_lba_mid_lsb = 0; scmd->satacmd_lba_high_lsb = 0; scmd->satacmd_features_reg = 0; scmd->satacmd_device_reg = 0; scmd->satacmd_status_reg = 0; if (scsipkt->pkt_cdbp[4] & 1) { /* Start Unit */ scmd->satacmd_cmd_reg = SATAC_IDLE_IM; } else { /* Stop Unit */ scmd->satacmd_cmd_reg = SATAC_STANDBY_IM; } if (!(spx->txlt_sata_pkt->satapkt_op_mode & SATA_OPMODE_SYNCH)) { /* Need to set-up a callback function */ spx->txlt_sata_pkt->satapkt_comp = sata_txlt_nodata_cmd_completion; synch = FALSE; } else { spx->txlt_sata_pkt->satapkt_op_mode = SATA_OPMODE_SYNCH; synch = TRUE; } /* Transfer command to HBA */ if (sata_hba_start(spx, &rval) != 0) { /* Pkt not accepted for execution */ mutex_exit(&SATA_CPORT_MUTEX(shi, cport)); return (rval); } /* * If execution is non-synchronous, * a callback function will handle potential errors, translate * the response and will do a callback to a target driver. * If it was synchronous, check execution status using the same * framework callback. */ mutex_exit(&SATA_CPORT_MUTEX(shi, cport)); if (synch) { SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "synchronous execution status %x\n", spx->txlt_sata_pkt->satapkt_reason); sata_txlt_nodata_cmd_completion(spx->txlt_sata_pkt); } return (TRAN_ACCEPT); } /* * SATA translate command: Read Capacity. * Emulated command for SATA disks. * Capacity is retrieved from cached Idenifty Device data. * Identify Device data shows effective disk capacity, not the native * capacity, which may be limitted by Set Max Address command. * This is ATA version (non-ATAPI). * * Returns TRAN_ACCEPT and appropriate values in scsi_pkt fields. */ static int sata_txlt_read_capacity(sata_pkt_txlate_t *spx) { struct scsi_pkt *scsipkt = spx->txlt_scsi_pkt; struct buf *bp = spx->txlt_sata_pkt->satapkt_cmd.satacmd_bp; sata_drive_info_t *sdinfo; uint64_t val; uchar_t *rbuf; int rval; SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "sata_txlt_read_capacity: ", NULL); mutex_enter(&(SATA_TXLT_CPORT_MUTEX(spx))); if ((rval = sata_txlt_generic_pkt_info(spx)) != TRAN_ACCEPT) { mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); return (rval); } scsipkt->pkt_reason = CMD_CMPLT; scsipkt->pkt_state = STATE_GOT_BUS | STATE_GOT_TARGET | STATE_SENT_CMD | STATE_GOT_STATUS; *scsipkt->pkt_scbp = STATUS_GOOD; if (bp != NULL && bp->b_un.b_addr && bp->b_bcount) { sdinfo = sata_get_device_info( spx->txlt_sata_hba_inst, &spx->txlt_sata_pkt->satapkt_device); /* Last logical block address */ val = sdinfo->satadrv_capacity - 1; rbuf = (uchar_t *)bp->b_un.b_addr; /* Need to swap endians to match scsi format */ rbuf[0] = (val >> 24) & 0xff; rbuf[1] = (val >> 16) & 0xff; rbuf[2] = (val >> 8) & 0xff; rbuf[3] = val & 0xff; /* block size - always 512 bytes, for now */ rbuf[4] = 0; rbuf[5] = 0; rbuf[6] = 0x02; rbuf[7] = 0; scsipkt->pkt_state |= STATE_XFERRED_DATA; scsipkt->pkt_resid = 0; SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "%d\n", sdinfo->satadrv_capacity -1); } mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); /* * If a callback was requested, do it now. */ SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "Scsi_pkt completion reason %x\n", scsipkt->pkt_reason); if ((scsipkt->pkt_flags & FLAG_NOINTR) == 0 && scsipkt->pkt_comp != NULL) /* scsi callback required */ (*scsipkt->pkt_comp)(scsipkt); return (TRAN_ACCEPT); } /* * SATA translate command: Mode Sense. * Translated into appropriate SATA command or emulated. * Saved Values Page Control (03) are not supported. * * NOTE: only caching mode sense page is currently implemented. * * Returns TRAN_ACCEPT and appropriate values in scsi_pkt fields. */ static int sata_txlt_mode_sense(sata_pkt_txlate_t *spx) { struct scsi_pkt *scsipkt = spx->txlt_scsi_pkt; struct buf *bp = spx->txlt_sata_pkt->satapkt_cmd.satacmd_bp; sata_drive_info_t *sdinfo; sata_id_t *sata_id; struct scsi_extended_sense *sense; int len, bdlen, count, alc_len; int pc; /* Page Control code */ uint8_t *buf; /* mode sense buffer */ int rval; SATADBG2(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "sata_txlt_mode_sense, pc %x page code 0x%02x\n", spx->txlt_scsi_pkt->pkt_cdbp[2] >> 6, spx->txlt_scsi_pkt->pkt_cdbp[2] & 0x3f); buf = kmem_zalloc(1024, KM_SLEEP); mutex_enter(&(SATA_TXLT_CPORT_MUTEX(spx))); if ((rval = sata_txlt_generic_pkt_info(spx)) != TRAN_ACCEPT) { mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); kmem_free(buf, 1024); return (rval); } scsipkt->pkt_reason = CMD_CMPLT; scsipkt->pkt_state = STATE_GOT_BUS | STATE_GOT_TARGET | STATE_SENT_CMD | STATE_GOT_STATUS; pc = scsipkt->pkt_cdbp[2] >> 6; if (bp != NULL && bp->b_un.b_addr && bp->b_bcount) { len = 0; bdlen = 0; if (!(scsipkt->pkt_cdbp[1] & 8)) { if (scsipkt->pkt_cdbp[0] == SCMD_MODE_SENSE_G1 && (scsipkt->pkt_cdbp[0] & 0x10)) bdlen = 16; else bdlen = 8; } /* Build mode parameter header */ if (spx->txlt_scsi_pkt->pkt_cdbp[0] == SCMD_MODE_SENSE) { /* 4-byte mode parameter header */ buf[len++] = 0; /* mode data length */ buf[len++] = 0; /* medium type */ buf[len++] = 0; /* dev-specific param */ buf[len++] = bdlen; /* Block Descriptor length */ } else { /* 8-byte mode parameter header */ buf[len++] = 0; /* mode data length */ buf[len++] = 0; buf[len++] = 0; /* medium type */ buf[len++] = 0; /* dev-specific param */ if (bdlen == 16) buf[len++] = 1; /* long lba descriptor */ else buf[len++] = 0; buf[len++] = 0; buf[len++] = 0; /* Block Descriptor length */ buf[len++] = bdlen; } sdinfo = sata_get_device_info( spx->txlt_sata_hba_inst, &spx->txlt_sata_pkt->satapkt_device); /* Build block descriptor only if not disabled (DBD) */ if ((scsipkt->pkt_cdbp[1] & 0x08) == 0) { /* Block descriptor - direct-access device format */ if (bdlen == 8) { /* build regular block descriptor */ buf[len++] = (sdinfo->satadrv_capacity >> 24) & 0xff; buf[len++] = (sdinfo->satadrv_capacity >> 16) & 0xff; buf[len++] = (sdinfo->satadrv_capacity >> 8) & 0xff; buf[len++] = sdinfo->satadrv_capacity & 0xff; buf[len++] = 0; /* density code */ buf[len++] = 0; if (sdinfo->satadrv_type == SATA_DTYPE_ATADISK) buf[len++] = 2; else /* ATAPI */ buf[len++] = 8; buf[len++] = 0; } else if (bdlen == 16) { /* Long LBA Accepted */ /* build long lba block descriptor */ #ifndef __lock_lint buf[len++] = (sdinfo->satadrv_capacity >> 56) & 0xff; buf[len++] = (sdinfo->satadrv_capacity >> 48) & 0xff; buf[len++] = (sdinfo->satadrv_capacity >> 40) & 0xff; buf[len++] = (sdinfo->satadrv_capacity >> 32) & 0xff; #endif buf[len++] = (sdinfo->satadrv_capacity >> 24) & 0xff; buf[len++] = (sdinfo->satadrv_capacity >> 16) & 0xff; buf[len++] = (sdinfo->satadrv_capacity >> 8) & 0xff; buf[len++] = sdinfo->satadrv_capacity & 0xff; buf[len++] = 0; buf[len++] = 0; /* density code */ buf[len++] = 0; buf[len++] = 0; if (sdinfo->satadrv_type == SATA_DTYPE_ATADISK) buf[len++] = 2; else /* ATAPI */ buf[len++] = 8; buf[len++] = 0; } } sata_id = &sdinfo->satadrv_id; /* * Add requested pages. * Page 3 and 4 are obsolete and we are not supporting them. * We deal now with: * caching (read/write cache control). * We should eventually deal with following mode pages: * error recovery (0x01), * power condition (0x1a), * exception control page (enables SMART) (0x1c), * enclosure management (ses), * protocol-specific port mode (port control). */ switch (scsipkt->pkt_cdbp[2] & 0x3f) { case MODEPAGE_RW_ERRRECOV: /* DAD_MODE_ERR_RECOV */ /* R/W recovery */ len += sata_build_msense_page_1(sdinfo, pc, buf+len); break; case MODEPAGE_CACHING: /* DAD_MODE_CACHE */ /* Reject not supported request for saved parameters */ if (pc == 3) { *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); sense->es_key = KEY_ILLEGAL_REQUEST; sense->es_add_code = SD_SCSI_SAVING_PARAMS_NOT_SUP; goto done; } /* caching */ len += sata_build_msense_page_8(sdinfo, pc, buf+len); break; case MODEPAGE_INFO_EXCPT: /* exception cntrl */ if (sata_id->ai_cmdset82 & SATA_SMART_SUPPORTED) { len += sata_build_msense_page_1c(sdinfo, pc, buf+len); } else goto err; break; case MODEPAGE_POWER_COND: /* DAD_MODE_POWER_COND */ /* power condition */ len += sata_build_msense_page_1a(sdinfo, pc, buf+len); break; case MODEPAGE_ALLPAGES: /* all pages */ len += sata_build_msense_page_1(sdinfo, pc, buf+len); len += sata_build_msense_page_8(sdinfo, pc, buf+len); len += sata_build_msense_page_1a(sdinfo, pc, buf+len); if (sata_id->ai_cmdset82 & SATA_SMART_SUPPORTED) { len += sata_build_msense_page_1c(sdinfo, pc, buf+len); } break; default: err: /* Invalid request */ *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); sense->es_key = KEY_ILLEGAL_REQUEST; sense->es_add_code = SD_SCSI_INVALID_FIELD_IN_CDB; goto done; } /* fix total mode data length */ if (spx->txlt_scsi_pkt->pkt_cdbp[0] == SCMD_MODE_SENSE) { /* 4-byte mode parameter header */ buf[0] = len - 1; /* mode data length */ } else { buf[0] = (len -2) >> 8; buf[1] = (len -2) & 0xff; } /* Check allocation length */ if (scsipkt->pkt_cdbp[0] == SCMD_MODE_SENSE) { alc_len = scsipkt->pkt_cdbp[4]; } else { alc_len = scsipkt->pkt_cdbp[7]; alc_len = (len << 8) | scsipkt->pkt_cdbp[8]; } /* * We do not check for possible parameters truncation * (alc_len < len) assuming that the target driver works * correctly. Just avoiding overrun. * Copy no more than requested and possible, buffer-wise. */ count = MIN(alc_len, len); count = MIN(bp->b_bcount, count); bcopy(buf, bp->b_un.b_addr, count); scsipkt->pkt_state |= STATE_XFERRED_DATA; scsipkt->pkt_resid = alc_len > count ? alc_len - count : 0; } *scsipkt->pkt_scbp = STATUS_GOOD; done: mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); (void) kmem_free(buf, 1024); SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "Scsi_pkt completion reason %x\n", scsipkt->pkt_reason); if ((scsipkt->pkt_flags & FLAG_NOINTR) == 0 && scsipkt->pkt_comp != NULL) /* scsi callback required */ (*scsipkt->pkt_comp)(scsipkt); return (TRAN_ACCEPT); } /* * SATA translate command: Mode Select. * Translated into appropriate SATA command or emulated. * Saving parameters is not supported. * Changing device capacity is not supported (although theoretically * possible by executing SET FEATURES/SET MAX ADDRESS) * * Assumption is that the target driver is working correctly. * * More than one SATA command may be executed to perform operations specified * by mode select pages. The first error terminates further execution. * Operations performed successully are not backed-up in such case. * * NOTE: only caching mode select page is implemented. * Caching setup is remembered so it could be re-stored in case of * an unexpected device reset. * * Returns TRAN_ACCEPT and appropriate values in scsi_pkt fields. */ static int sata_txlt_mode_select(sata_pkt_txlate_t *spx) { struct scsi_pkt *scsipkt = spx->txlt_scsi_pkt; struct buf *bp = spx->txlt_sata_pkt->satapkt_cmd.satacmd_bp; struct scsi_extended_sense *sense; int len, pagelen, count, pllen; uint8_t *buf; /* mode select buffer */ int rval, stat; uint_t nointr_flag; int dmod = 0; SATADBG2(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "sata_txlt_mode_select, pc %x page code 0x%02x\n", spx->txlt_scsi_pkt->pkt_cdbp[2] >> 6, spx->txlt_scsi_pkt->pkt_cdbp[2] & 0x3f); mutex_enter(&(SATA_TXLT_CPORT_MUTEX(spx))); if ((rval = sata_txlt_generic_pkt_info(spx)) != TRAN_ACCEPT) { mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); return (rval); } rval = TRAN_ACCEPT; scsipkt->pkt_reason = CMD_CMPLT; scsipkt->pkt_state = STATE_GOT_BUS | STATE_GOT_TARGET | STATE_SENT_CMD | STATE_GOT_STATUS; /* Reject not supported request */ if (! (scsipkt->pkt_cdbp[1] & 0x10)) { /* No support for PF bit = 0 */ *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); sense->es_key = KEY_ILLEGAL_REQUEST; sense->es_add_code = SD_SCSI_INVALID_FIELD_IN_CDB; goto done; } if (scsipkt->pkt_cdbp[0] == SCMD_MODE_SELECT) { pllen = scsipkt->pkt_cdbp[4]; } else { pllen = scsipkt->pkt_cdbp[7]; pllen = (pllen << 8) | scsipkt->pkt_cdbp[7]; } *scsipkt->pkt_scbp = STATUS_GOOD; /* Presumed outcome */ if (bp != NULL && bp->b_un.b_addr && bp->b_bcount && pllen != 0) { buf = (uint8_t *)bp->b_un.b_addr; count = MIN(bp->b_bcount, pllen); scsipkt->pkt_state |= STATE_XFERRED_DATA; scsipkt->pkt_resid = 0; pllen = count; /* * Check the header to skip the block descriptor(s) - we * do not support setting device capacity. * Existing macros do not recognize long LBA dscriptor, * hence manual calculation. */ if (scsipkt->pkt_cdbp[0] == SCMD_MODE_SELECT) { /* 6-bytes CMD, 4 bytes header */ if (count <= 4) goto done; /* header only */ len = buf[3] + 4; } else { /* 10-bytes CMD, 8 bytes header */ if (count <= 8) goto done; /* header only */ len = buf[6]; len = (len << 8) + buf[7] + 8; } if (len >= count) goto done; /* header + descriptor(s) only */ pllen -= len; /* remaining data length */ /* * We may be executing SATA command and want to execute it * in SYNCH mode, regardless of scsi_pkt setting. * Save scsi_pkt setting and indicate SYNCH mode */ nointr_flag = scsipkt->pkt_flags & FLAG_NOINTR; if ((scsipkt->pkt_flags & FLAG_NOINTR) == 0 && scsipkt->pkt_comp != NULL) { scsipkt->pkt_flags |= FLAG_NOINTR; } spx->txlt_sata_pkt->satapkt_op_mode = SATA_OPMODE_SYNCH; /* * len is now the offset to a first mode select page * Process all pages */ while (pllen > 0) { switch ((int)buf[len]) { case MODEPAGE_CACHING: /* No support for SP (saving) */ if (scsipkt->pkt_cdbp[1] & 0x01) { *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); sense->es_key = KEY_ILLEGAL_REQUEST; sense->es_add_code = SD_SCSI_INVALID_FIELD_IN_CDB; goto done; } stat = sata_mode_select_page_8(spx, (struct mode_cache_scsi3 *)&buf[len], pllen, &pagelen, &rval, &dmod); /* * The pagelen value indicates the number of * parameter bytes already processed. * The rval is the return value from * sata_tran_start(). * The stat indicates the overall status of * the operation(s). */ if (stat != SATA_SUCCESS) /* * Page processing did not succeed - * all error info is already set-up, * just return */ pllen = 0; /* this breaks the loop */ else { len += pagelen; pllen -= pagelen; } break; case MODEPAGE_INFO_EXCPT: stat = sata_mode_select_page_1c(spx, (struct mode_info_excpt_page *)&buf[len], pllen, &pagelen, &rval, &dmod); /* * The pagelen value indicates the number of * parameter bytes already processed. * The rval is the return value from * sata_tran_start(). * The stat indicates the overall status of * the operation(s). */ if (stat != SATA_SUCCESS) /* * Page processing did not succeed - * all error info is already set-up, * just return */ pllen = 0; /* this breaks the loop */ else { len += pagelen; pllen -= pagelen; } break; default: *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); sense->es_key = KEY_ILLEGAL_REQUEST; sense->es_add_code = SD_SCSI_INVALID_FIELD_IN_PARAMETER_LIST; goto done; } } } done: mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); /* * If device parameters were modified, fetch and store the new * Identify Device data. Since port mutex could have been released * for accessing HBA driver, we need to re-check device existence. */ if (dmod != 0) { sata_drive_info_t new_sdinfo, *sdinfo; int rv; new_sdinfo.satadrv_addr = spx->txlt_sata_pkt->satapkt_device.satadev_addr; rv = sata_fetch_device_identify_data(spx->txlt_sata_hba_inst, &new_sdinfo); mutex_enter(&(SATA_TXLT_CPORT_MUTEX(spx))); /* * Since port mutex could have been released when * accessing HBA driver, we need to re-check that the * framework still holds the device info structure. */ sdinfo = sata_get_device_info(spx->txlt_sata_hba_inst, &spx->txlt_sata_pkt->satapkt_device); if (sdinfo != NULL) { /* * Device still has info structure in the * sata framework. Copy newly fetched info */ if (rv == 0) { sdinfo->satadrv_id = new_sdinfo.satadrv_id; sata_save_drive_settings(sdinfo); } else { /* * Could not fetch new data - invalidate * sata_drive_info. That makes device * unusable. */ sdinfo->satadrv_type = SATA_DTYPE_UNKNOWN; sdinfo->satadrv_state = SATA_STATE_UNKNOWN; } } if (rv != 0 || sdinfo == NULL) { /* * This changes the overall mode select completion * reason to a failed one !!!!! */ *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); scsipkt->pkt_reason = CMD_INCOMPLETE; rval = TRAN_ACCEPT; } mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); } /* Restore the scsi pkt flags */ scsipkt->pkt_flags &= ~FLAG_NOINTR; scsipkt->pkt_flags |= nointr_flag; SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "Scsi_pkt completion reason %x\n", scsipkt->pkt_reason); if ((scsipkt->pkt_flags & FLAG_NOINTR) == 0 && scsipkt->pkt_comp != NULL) /* scsi callback required */ (*scsipkt->pkt_comp)(scsipkt); return (rval); } /* * Translate command: Log Sense */ static int sata_txlt_log_sense(sata_pkt_txlate_t *spx) { struct scsi_pkt *scsipkt = spx->txlt_scsi_pkt; struct buf *bp = spx->txlt_sata_pkt->satapkt_cmd.satacmd_bp; sata_drive_info_t *sdinfo; struct scsi_extended_sense *sense; int len, count, alc_len; int pc; /* Page Control code */ int page_code; /* Page code */ uint8_t *buf; /* log sense buffer */ int rval; #define MAX_LOG_SENSE_PAGE_SIZE 512 SATADBG2(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "sata_txlt_log_sense, pc 0x%x, page code 0x%x\n", spx->txlt_scsi_pkt->pkt_cdbp[2] >> 6, spx->txlt_scsi_pkt->pkt_cdbp[2] & 0x3f); buf = kmem_zalloc(MAX_LOG_SENSE_PAGE_SIZE, KM_SLEEP); mutex_enter(&(SATA_TXLT_CPORT_MUTEX(spx))); if ((rval = sata_txlt_generic_pkt_info(spx)) != TRAN_ACCEPT) { mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); kmem_free(buf, MAX_LOG_SENSE_PAGE_SIZE); return (rval); } scsipkt->pkt_reason = CMD_CMPLT; scsipkt->pkt_state = STATE_GOT_BUS | STATE_GOT_TARGET | STATE_SENT_CMD | STATE_GOT_STATUS; pc = scsipkt->pkt_cdbp[2] >> 6; page_code = scsipkt->pkt_cdbp[2] & 0x3f; /* Reject not supported request for all but cummulative values */ switch (pc) { case PC_CUMMULATIVE_VALUES: break; default: *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); sense->es_key = KEY_ILLEGAL_REQUEST; sense->es_add_code = SD_SCSI_INVALID_FIELD_IN_CDB; goto done; } switch (page_code) { case PAGE_CODE_GET_SUPPORTED_LOG_PAGES: case PAGE_CODE_SELF_TEST_RESULTS: case PAGE_CODE_INFORMATION_EXCEPTIONS: case PAGE_CODE_SMART_READ_DATA: break; default: *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); sense->es_key = KEY_ILLEGAL_REQUEST; sense->es_add_code = SD_SCSI_INVALID_FIELD_IN_CDB; goto done; } if (bp != NULL && bp->b_un.b_addr && bp->b_bcount) { sata_id_t *sata_id; len = 0; /* Build log parameter header */ buf[len++] = page_code; /* page code as in the CDB */ buf[len++] = 0; /* reserved */ buf[len++] = 0; /* Zero out page length for now (MSB) */ buf[len++] = 0; /* (LSB) */ sdinfo = sata_get_device_info( spx->txlt_sata_hba_inst, &spx->txlt_sata_pkt->satapkt_device); /* * Add requested pages. */ switch (page_code) { case PAGE_CODE_GET_SUPPORTED_LOG_PAGES: len = sata_build_lsense_page_0(sdinfo, buf + len); break; case PAGE_CODE_SELF_TEST_RESULTS: sata_id = &sdinfo->satadrv_id; if ((! (sata_id->ai_cmdset84 & SATA_SMART_SELF_TEST_SUPPORTED)) || (! (sata_id->ai_features87 & SATA_SMART_SELF_TEST_SUPPORTED))) { *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); sense->es_key = KEY_ILLEGAL_REQUEST; sense->es_add_code = SD_SCSI_INVALID_FIELD_IN_CDB; goto done; } len = sata_build_lsense_page_10(sdinfo, buf + len, spx->txlt_sata_hba_inst); break; case PAGE_CODE_INFORMATION_EXCEPTIONS: sata_id = &sdinfo->satadrv_id; if (! (sata_id->ai_cmdset82 & SATA_SMART_SUPPORTED)) { *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); sense->es_key = KEY_ILLEGAL_REQUEST; sense->es_add_code = SD_SCSI_INVALID_FIELD_IN_CDB; goto done; } if (! (sata_id->ai_features85 & SATA_SMART_ENABLED)) { *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); sense->es_key = KEY_ABORTED_COMMAND; sense->es_add_code = SCSI_ASC_ATA_DEV_FEAT_NOT_ENABLED; sense->es_qual_code = SCSI_ASCQ_ATA_DEV_FEAT_NOT_ENABLED; goto done; } len = sata_build_lsense_page_2f(sdinfo, buf + len, spx->txlt_sata_hba_inst); break; case PAGE_CODE_SMART_READ_DATA: sata_id = &sdinfo->satadrv_id; if (! (sata_id->ai_cmdset82 & SATA_SMART_SUPPORTED)) { *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); sense->es_key = KEY_ILLEGAL_REQUEST; sense->es_add_code = SD_SCSI_INVALID_FIELD_IN_CDB; goto done; } if (! (sata_id->ai_features85 & SATA_SMART_ENABLED)) { *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); sense->es_key = KEY_ABORTED_COMMAND; sense->es_add_code = SCSI_ASC_ATA_DEV_FEAT_NOT_ENABLED; sense->es_qual_code = SCSI_ASCQ_ATA_DEV_FEAT_NOT_ENABLED; goto done; } /* This page doesn't include a page header */ len = sata_build_lsense_page_30(sdinfo, buf, spx->txlt_sata_hba_inst); goto no_header; default: /* Invalid request */ *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); sense->es_key = KEY_ILLEGAL_REQUEST; sense->es_add_code = SD_SCSI_INVALID_FIELD_IN_CDB; goto done; } /* set parameter log sense data length */ buf[2] = len >> 8; /* log sense length (MSB) */ buf[3] = len & 0xff; /* log sense length (LSB) */ len += SCSI_LOG_PAGE_HDR_LEN; ASSERT(len <= MAX_LOG_SENSE_PAGE_SIZE); no_header: /* Check allocation length */ alc_len = scsipkt->pkt_cdbp[7]; alc_len = (len << 8) | scsipkt->pkt_cdbp[8]; /* * We do not check for possible parameters truncation * (alc_len < len) assuming that the target driver works * correctly. Just avoiding overrun. * Copy no more than requested and possible, buffer-wise. */ count = MIN(alc_len, len); count = MIN(bp->b_bcount, count); bcopy(buf, bp->b_un.b_addr, count); scsipkt->pkt_state |= STATE_XFERRED_DATA; scsipkt->pkt_resid = alc_len > count ? alc_len - count : 0; } *scsipkt->pkt_scbp = STATUS_GOOD; done: mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); (void) kmem_free(buf, MAX_LOG_SENSE_PAGE_SIZE); SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "Scsi_pkt completion reason %x\n", scsipkt->pkt_reason); if ((scsipkt->pkt_flags & FLAG_NOINTR) == 0 && scsipkt->pkt_comp != NULL) /* scsi callback required */ (*scsipkt->pkt_comp)(scsipkt); return (TRAN_ACCEPT); } /* * Translate command: Log Select * Not implemented at this time - returns invalid command response. */ static int sata_txlt_log_select(sata_pkt_txlate_t *spx) { SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "sata_txlt_log_select\n", NULL); return (sata_txlt_invalid_command(spx)); } /* * Translate command: Read (various types). * Translated into appropriate type of ATA READ command * (NO ATAPI implementation yet). * Both the device capabilities and requested operation mode are * considered. * * Following scsi cdb fields are ignored: * rdprotect, dpo, fua, fua_nv, group_number. * * If SATA_ENABLE_QUEUING flag is set (in the global SATA HBA framework * enable variable sata_func_enable), the capability of the controller and * capability of a device are checked and if both support queueing, read * request will be translated to READ_DMA_QUEUEING or READ_DMA_QUEUEING_EXT * command rather than plain READ_XXX command. * If SATA_ENABLE_NCQ flag is set in addition to SATA_ENABLE_QUEUING flag and * both the controller and device suport such functionality, the read * request will be translated to READ_FPDMA_QUEUED command. * * Returns TRAN_ACCEPT or code returned by sata_hba_start() and * appropriate values in scsi_pkt fields. */ static int sata_txlt_read(sata_pkt_txlate_t *spx) { struct scsi_pkt *scsipkt = spx->txlt_scsi_pkt; sata_cmd_t *scmd = &spx->txlt_sata_pkt->satapkt_cmd; sata_drive_info_t *sdinfo; sata_hba_inst_t *shi = SATA_TXLT_HBA_INST(spx); int cport = SATA_TXLT_CPORT(spx); uint16_t sec_count; uint64_t lba; int rval; int synch; mutex_enter(&(SATA_TXLT_CPORT_MUTEX(spx))); if ((rval = sata_txlt_generic_pkt_info(spx)) != TRAN_ACCEPT) { mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); return (rval); } sdinfo = sata_get_device_info(spx->txlt_sata_hba_inst, &spx->txlt_sata_pkt->satapkt_device); scmd->satacmd_flags.sata_data_direction = SATA_DIR_READ; /* * Build cmd block depending on the device capability and * requested operation mode. * Do not bother with non-dma mode. */ switch ((uint_t)scsipkt->pkt_cdbp[0]) { case SCMD_READ: /* 6-byte scsi read cmd : 0x08 */ lba = (scsipkt->pkt_cdbp[1] & 0x1f); lba = (lba << 8) | scsipkt->pkt_cdbp[2]; lba = (lba << 8) | scsipkt->pkt_cdbp[3]; sec_count = scsipkt->pkt_cdbp[4]; /* sec_count 0 will be interpreted as 256 by a device */ break; case SCMD_READ_G1: /* 10-bytes scsi read command : 0x28 */ lba = scsipkt->pkt_cdbp[2]; lba = (lba << 8) | scsipkt->pkt_cdbp[3]; lba = (lba << 8) | scsipkt->pkt_cdbp[4]; lba = (lba << 8) | scsipkt->pkt_cdbp[5]; sec_count = scsipkt->pkt_cdbp[7]; sec_count = (sec_count << 8) | scsipkt->pkt_cdbp[8]; break; case SCMD_READ_G5: /* 12-bytes scsi read command : 0xA8 */ lba = scsipkt->pkt_cdbp[2]; lba = (lba << 8) | scsipkt->pkt_cdbp[3]; lba = (lba << 8) | scsipkt->pkt_cdbp[4]; lba = (lba << 8) | scsipkt->pkt_cdbp[5]; sec_count = scsipkt->pkt_cdbp[6]; sec_count = (sec_count << 8) | scsipkt->pkt_cdbp[7]; sec_count = (sec_count << 8) | scsipkt->pkt_cdbp[8]; sec_count = (sec_count << 8) | scsipkt->pkt_cdbp[9]; break; case SCMD_READ_G4: /* 16-bytes scsi read command : 0x88 */ lba = scsipkt->pkt_cdbp[2]; lba = (lba << 8) | scsipkt->pkt_cdbp[3]; lba = (lba << 8) | scsipkt->pkt_cdbp[4]; lba = (lba << 8) | scsipkt->pkt_cdbp[5]; lba = (lba << 8) | scsipkt->pkt_cdbp[6]; lba = (lba << 8) | scsipkt->pkt_cdbp[7]; lba = (lba << 8) | scsipkt->pkt_cdbp[8]; lba = (lba << 8) | scsipkt->pkt_cdbp[9]; sec_count = scsipkt->pkt_cdbp[10]; sec_count = (sec_count << 8) | scsipkt->pkt_cdbp[11]; sec_count = (sec_count << 8) | scsipkt->pkt_cdbp[12]; sec_count = (sec_count << 8) | scsipkt->pkt_cdbp[13]; break; default: /* Unsupported command */ mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); return (sata_txlt_invalid_command(spx)); } /* * Check if specified address exceeds device capacity */ if ((lba >= sdinfo->satadrv_capacity) || ((lba + sec_count) >= sdinfo->satadrv_capacity)) { /* LBA out of range */ mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); return (sata_txlt_lba_out_of_range(spx)); } scmd->satacmd_addr_type = ATA_ADDR_LBA; scmd->satacmd_device_reg = SATA_ADH_LBA; scmd->satacmd_cmd_reg = SATAC_READ_DMA; if (sdinfo->satadrv_features_support & SATA_DEV_F_LBA48) { scmd->satacmd_addr_type = ATA_ADDR_LBA48; scmd->satacmd_cmd_reg = SATAC_READ_DMA_EXT; scmd->satacmd_sec_count_msb = sec_count >> 8; #ifndef __lock_lint scmd->satacmd_lba_low_msb = (lba >> 24) & 0xff; scmd->satacmd_lba_mid_msb = (lba >> 32) & 0xff; scmd->satacmd_lba_high_msb = lba >> 40; #endif } else if (sdinfo->satadrv_features_support & SATA_DEV_F_LBA28) { scmd->satacmd_addr_type = ATA_ADDR_LBA28; scmd->satacmd_device_reg = SATA_ADH_LBA | ((lba >> 24) & 0xf); } scmd->satacmd_sec_count_lsb = sec_count & 0xff; scmd->satacmd_lba_low_lsb = lba & 0xff; scmd->satacmd_lba_mid_lsb = (lba >> 8) & 0xff; scmd->satacmd_lba_high_lsb = (lba >> 16) & 0xff; scmd->satacmd_features_reg = 0; scmd->satacmd_status_reg = 0; scmd->satacmd_error_reg = 0; /* * Check if queueing commands should be used and switch * to appropriate command if possible */ if (sata_func_enable & SATA_ENABLE_QUEUING) { if (sdinfo->satadrv_queue_depth > 1 && SATA_QDEPTH(spx->txlt_sata_hba_inst) > 1) { /* Queuing supported by controller and device */ if ((sata_func_enable & SATA_ENABLE_NCQ) && (sdinfo->satadrv_features_support & SATA_DEV_F_NCQ) && (SATA_FEATURES(spx->txlt_sata_hba_inst) & SATA_CTLF_NCQ)) { /* NCQ supported - use FPDMA READ */ scmd->satacmd_cmd_reg = SATAC_READ_FPDMA_QUEUED; scmd->satacmd_features_reg_ext = scmd->satacmd_sec_count_msb; scmd->satacmd_sec_count_msb = 0; } else { /* Legacy queueing */ if (sdinfo->satadrv_features_support & SATA_DEV_F_LBA48) { scmd->satacmd_cmd_reg = SATAC_READ_DMA_QUEUED_EXT; scmd->satacmd_features_reg_ext = scmd->satacmd_sec_count_msb; scmd->satacmd_sec_count_msb = 0; } else { scmd->satacmd_cmd_reg = SATAC_READ_DMA_QUEUED; } } scmd->satacmd_features_reg = scmd->satacmd_sec_count_lsb; scmd->satacmd_sec_count_lsb = 0; scmd->satacmd_flags.sata_queued = B_TRUE; } } SATADBG3(SATA_DBG_HBA_IF, spx->txlt_sata_hba_inst, "sata_txlt_read cmd 0x%2x, lba %llx, sec count %x\n", scmd->satacmd_cmd_reg, lba, sec_count); if (!(spx->txlt_sata_pkt->satapkt_op_mode & SATA_OPMODE_SYNCH)) { /* Need callback function */ spx->txlt_sata_pkt->satapkt_comp = sata_txlt_rw_completion; synch = FALSE; } else synch = TRUE; /* Transfer command to HBA */ if (sata_hba_start(spx, &rval) != 0) { /* Pkt not accepted for execution */ mutex_exit(&SATA_CPORT_MUTEX(shi, cport)); return (rval); } mutex_exit(&SATA_CPORT_MUTEX(shi, cport)); /* * If execution is non-synchronous, * a callback function will handle potential errors, translate * the response and will do a callback to a target driver. * If it was synchronous, check execution status using the same * framework callback. */ if (synch) { SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "synchronous execution status %x\n", spx->txlt_sata_pkt->satapkt_reason); sata_txlt_rw_completion(spx->txlt_sata_pkt); } return (TRAN_ACCEPT); } /* * SATA translate command: Write (various types) * Translated into appropriate type of ATA WRITE command * (NO ATAPI implementation yet). * Both the device capabilities and requested operation mode are * considered. * * Following scsi cdb fields are ignored: * rwprotect, dpo, fua, fua_nv, group_number. * * Returns TRAN_ACCEPT or code returned by sata_hba_start() and * appropriate values in scsi_pkt fields. */ static int sata_txlt_write(sata_pkt_txlate_t *spx) { struct scsi_pkt *scsipkt = spx->txlt_scsi_pkt; sata_cmd_t *scmd = &spx->txlt_sata_pkt->satapkt_cmd; sata_drive_info_t *sdinfo; sata_hba_inst_t *shi = SATA_TXLT_HBA_INST(spx); int cport = SATA_TXLT_CPORT(spx); uint16_t sec_count; uint64_t lba; int rval; int synch; mutex_enter(&(SATA_TXLT_CPORT_MUTEX(spx))); if ((rval = sata_txlt_generic_pkt_info(spx)) != TRAN_ACCEPT) { mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); return (rval); } sdinfo = sata_get_device_info(spx->txlt_sata_hba_inst, &spx->txlt_sata_pkt->satapkt_device); scmd->satacmd_flags.sata_data_direction = SATA_DIR_WRITE; /* * Build cmd block depending on the device capability and * requested operation mode. * Do not bother with non-dma mode. */ switch ((uint_t)scsipkt->pkt_cdbp[0]) { case SCMD_WRITE: /* 6-byte scsi read cmd : 0x0A */ lba = (scsipkt->pkt_cdbp[1] & 0x1f); lba = (lba << 8) | scsipkt->pkt_cdbp[2]; lba = (lba << 8) | scsipkt->pkt_cdbp[3]; sec_count = scsipkt->pkt_cdbp[4]; /* sec_count 0 will be interpreted as 256 by a device */ break; case SCMD_WRITE_G1: /* 10-bytes scsi write command : 0x2A */ lba = scsipkt->pkt_cdbp[2]; lba = (lba << 8) | scsipkt->pkt_cdbp[3]; lba = (lba << 8) | scsipkt->pkt_cdbp[4]; lba = (lba << 8) | scsipkt->pkt_cdbp[5]; sec_count = scsipkt->pkt_cdbp[7]; sec_count = (sec_count << 8) | scsipkt->pkt_cdbp[8]; break; case SCMD_WRITE_G5: /* 12-bytes scsi read command : 0xAA */ lba = scsipkt->pkt_cdbp[2]; lba = (lba << 8) | scsipkt->pkt_cdbp[3]; lba = (lba << 8) | scsipkt->pkt_cdbp[4]; lba = (lba << 8) | scsipkt->pkt_cdbp[5]; sec_count = scsipkt->pkt_cdbp[6]; sec_count = (sec_count << 8) | scsipkt->pkt_cdbp[7]; sec_count = (sec_count << 8) | scsipkt->pkt_cdbp[8]; sec_count = (sec_count << 8) | scsipkt->pkt_cdbp[9]; break; case SCMD_WRITE_G4: /* 16-bytes scsi write command : 0x8A */ lba = scsipkt->pkt_cdbp[2]; lba = (lba << 8) | scsipkt->pkt_cdbp[3]; lba = (lba << 8) | scsipkt->pkt_cdbp[4]; lba = (lba << 8) | scsipkt->pkt_cdbp[5]; lba = (lba << 8) | scsipkt->pkt_cdbp[6]; lba = (lba << 8) | scsipkt->pkt_cdbp[7]; lba = (lba << 8) | scsipkt->pkt_cdbp[8]; lba = (lba << 8) | scsipkt->pkt_cdbp[9]; sec_count = scsipkt->pkt_cdbp[10]; sec_count = (sec_count << 8) | scsipkt->pkt_cdbp[11]; sec_count = (sec_count << 8) | scsipkt->pkt_cdbp[12]; sec_count = (sec_count << 8) | scsipkt->pkt_cdbp[13]; break; default: /* Unsupported command */ mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); return (sata_txlt_invalid_command(spx)); } /* * Check if specified address and length exceeds device capacity */ if ((lba >= sdinfo->satadrv_capacity) || ((lba + sec_count) >= sdinfo->satadrv_capacity)) { /* LBA out of range */ mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); return (sata_txlt_lba_out_of_range(spx)); } scmd->satacmd_addr_type = ATA_ADDR_LBA; scmd->satacmd_device_reg = SATA_ADH_LBA; scmd->satacmd_cmd_reg = SATAC_WRITE_DMA; if (sdinfo->satadrv_features_support & SATA_DEV_F_LBA48) { scmd->satacmd_addr_type = ATA_ADDR_LBA48; scmd->satacmd_cmd_reg = SATAC_WRITE_DMA_EXT; scmd->satacmd_sec_count_msb = sec_count >> 8; scmd->satacmd_lba_low_msb = (lba >> 24) & 0xff; #ifndef __lock_lint scmd->satacmd_lba_mid_msb = (lba >> 32) & 0xff; scmd->satacmd_lba_high_msb = lba >> 40; #endif } else if (sdinfo->satadrv_features_support & SATA_DEV_F_LBA28) { scmd->satacmd_addr_type = ATA_ADDR_LBA28; scmd->satacmd_device_reg = SATA_ADH_LBA | ((lba >> 24) & 0xf); } scmd->satacmd_sec_count_lsb = sec_count & 0xff; scmd->satacmd_lba_low_lsb = lba & 0xff; scmd->satacmd_lba_mid_lsb = (lba >> 8) & 0xff; scmd->satacmd_lba_high_lsb = (lba >> 16) & 0xff; scmd->satacmd_features_reg = 0; scmd->satacmd_status_reg = 0; scmd->satacmd_error_reg = 0; /* * Check if queueing commands should be used and switch * to appropriate command if possible */ if (sata_func_enable & SATA_ENABLE_QUEUING) { if (sdinfo->satadrv_queue_depth > 1 && SATA_QDEPTH(spx->txlt_sata_hba_inst) > 1) { /* Queuing supported by controller and device */ if ((sata_func_enable & SATA_ENABLE_NCQ) && (sdinfo->satadrv_features_support & SATA_DEV_F_NCQ) && (SATA_FEATURES(spx->txlt_sata_hba_inst) & SATA_CTLF_NCQ)) { /* NCQ supported - use FPDMA WRITE */ scmd->satacmd_cmd_reg = SATAC_WRITE_FPDMA_QUEUED; scmd->satacmd_features_reg_ext = scmd->satacmd_sec_count_msb; scmd->satacmd_sec_count_msb = 0; scmd->satacmd_rle_sata_cmd = NULL; } else { /* Legacy queueing */ if (sdinfo->satadrv_features_support & SATA_DEV_F_LBA48) { scmd->satacmd_cmd_reg = SATAC_WRITE_DMA_QUEUED_EXT; scmd->satacmd_features_reg_ext = scmd->satacmd_sec_count_msb; scmd->satacmd_sec_count_msb = 0; } else { scmd->satacmd_cmd_reg = SATAC_WRITE_DMA_QUEUED; } } scmd->satacmd_features_reg = scmd->satacmd_sec_count_lsb; scmd->satacmd_sec_count_lsb = 0; scmd->satacmd_flags.sata_queued = B_TRUE; } } SATADBG3(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "sata_txlt_write cmd 0x%2x, lba %llx, sec count %x\n", scmd->satacmd_cmd_reg, lba, sec_count); if (!(spx->txlt_sata_pkt->satapkt_op_mode & SATA_OPMODE_SYNCH)) { /* Need callback function */ spx->txlt_sata_pkt->satapkt_comp = sata_txlt_rw_completion; synch = FALSE; } else synch = TRUE; /* Transfer command to HBA */ if (sata_hba_start(spx, &rval) != 0) { /* Pkt not accepted for execution */ mutex_exit(&SATA_CPORT_MUTEX(shi, cport)); return (rval); } mutex_exit(&SATA_CPORT_MUTEX(shi, cport)); /* * If execution is non-synchronous, * a callback function will handle potential errors, translate * the response and will do a callback to a target driver. * If it was synchronous, check execution status using the same * framework callback. */ if (synch) { SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "synchronous execution status %x\n", spx->txlt_sata_pkt->satapkt_reason); sata_txlt_rw_completion(spx->txlt_sata_pkt); } return (TRAN_ACCEPT); } /* * NOTE: NOT FUNCTIONAL IMPLEMENTATION. THIS IS A PLACEHOLDER for the function * that will be fixed in phase 2 of the development. * Currently ATAPI is not supported. ATAPI devices are threated as not-valid * devices. * This function is not called, since scsi_sata_start() will bail-out prior * to calling it. */ static int sata_txlt_atapi(sata_pkt_txlate_t *spx) { struct scsi_pkt *scsipkt = spx->txlt_scsi_pkt; sata_cmd_t *scmd = &spx->txlt_sata_pkt->satapkt_cmd; struct buf *bp = spx->txlt_sata_pkt->satapkt_cmd.satacmd_bp; sata_hba_inst_t *shi = SATA_TXLT_HBA_INST(spx); int cport = SATA_TXLT_CPORT(spx); int rval; int synch; union scsi_cdb *cdbp = (union scsi_cdb *)scsipkt->pkt_cdbp; mutex_enter(&(SATA_TXLT_CPORT_MUTEX(spx))); if ((rval = sata_txlt_generic_pkt_info(spx)) != TRAN_ACCEPT) { mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); return (rval); } /* * scmd->satacmd_flags.sata_data_direction default - * SATA_DIR_NODATA_XFER - is set by * sata_txlt_generic_pkt_info(). */ if (scmd->satacmd_bp) { if (scmd->satacmd_bp->b_flags & B_READ) { scmd->satacmd_flags.sata_data_direction = SATA_DIR_READ; } else { scmd->satacmd_flags.sata_data_direction = SATA_DIR_WRITE; } } scmd->satacmd_acdb_len = scsi_cdb_size[GETGROUP(cdbp)]; scmd->satacmd_cmd_reg = SATAC_PACKET; bcopy(cdbp, scmd->satacmd_acdb, 16); /* * For non-read/write commands we need to * map buffer */ switch ((uint_t)scsipkt->pkt_cdbp[0]) { case SCMD_READ: case SCMD_READ_G1: case SCMD_READ_G5: case SCMD_READ_G4: case SCMD_WRITE: case SCMD_WRITE_G1: case SCMD_WRITE_G5: case SCMD_WRITE_G4: break; default: if (bp->b_flags & (B_PHYS | B_PAGEIO)) bp_mapin(bp); break; } if (!(spx->txlt_sata_pkt->satapkt_op_mode & SATA_OPMODE_SYNCH)) { /* Need callback function */ spx->txlt_sata_pkt->satapkt_comp = sata_txlt_atapi_completion; synch = FALSE; } else synch = TRUE; /* Transfer command to HBA */ if (sata_hba_start(spx, &rval) != 0) { /* Pkt not accepted for execution */ mutex_exit(&SATA_CPORT_MUTEX(shi, cport)); return (rval); } mutex_exit(&SATA_CPORT_MUTEX(shi, cport)); /* * If execution is non-synchronous, * a callback function will handle potential errors, translate * the response and will do a callback to a target driver. * If it was synchronous, check execution status using the same * framework callback. */ if (synch) { SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "synchronous execution status %x\n", spx->txlt_sata_pkt->satapkt_reason); sata_txlt_atapi_completion(spx->txlt_sata_pkt); } return (TRAN_ACCEPT); } /* * Translate command: Synchronize Cache. * Translates into Flush Cache command. * (NO ATAPI implementation yet). * * NOTE: We should check if Flush Cache is supported by the device (ATAPI * devices) * * Returns TRAN_ACCEPT or code returned by sata_hba_start() and * appropriate values in scsi_pkt fields. */ static int sata_txlt_synchronize_cache(sata_pkt_txlate_t *spx) { sata_cmd_t *scmd = &spx->txlt_sata_pkt->satapkt_cmd; sata_hba_inst_t *shi = SATA_TXLT_HBA_INST(spx); int cport = SATA_TXLT_CPORT(spx); int rval; int synch; mutex_enter(&(SATA_TXLT_CPORT_MUTEX(spx))); if ((rval = sata_txlt_generic_pkt_info(spx)) != TRAN_ACCEPT) { mutex_exit(&(SATA_TXLT_CPORT_MUTEX(spx))); return (rval); } scmd->satacmd_addr_type = 0; scmd->satacmd_cmd_reg = SATAC_FLUSH_CACHE; scmd->satacmd_device_reg = 0; scmd->satacmd_sec_count_lsb = 0; scmd->satacmd_lba_low_lsb = 0; scmd->satacmd_lba_mid_lsb = 0; scmd->satacmd_lba_high_lsb = 0; scmd->satacmd_features_reg = 0; scmd->satacmd_status_reg = 0; scmd->satacmd_error_reg = 0; SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "sata_txlt_synchronize_cache\n", NULL); if (!(spx->txlt_sata_pkt->satapkt_op_mode & SATA_OPMODE_SYNCH)) { /* Need to set-up a callback function */ spx->txlt_sata_pkt->satapkt_comp = sata_txlt_nodata_cmd_completion; synch = FALSE; } else synch = TRUE; /* Transfer command to HBA */ if (sata_hba_start(spx, &rval) != 0) { /* Pkt not accepted for execution */ mutex_exit(&SATA_CPORT_MUTEX(shi, cport)); return (rval); } mutex_exit(&SATA_CPORT_MUTEX(shi, cport)); /* * If execution non-synchronous, it had to be completed * a callback function will handle potential errors, translate * the response and will do a callback to a target driver. * If it was synchronous, check status, using the same * framework callback. */ if (synch) { SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "synchronous execution status %x\n", spx->txlt_sata_pkt->satapkt_reason); sata_txlt_nodata_cmd_completion(spx->txlt_sata_pkt); } return (TRAN_ACCEPT); } /* * Send pkt to SATA HBA driver * * This function may be called only if the operation is requested by scsi_pkt, * i.e. scsi_pkt is not NULL. * * This function has to be called with cport mutex held. It does release * the mutex when it calls HBA driver sata_tran_start function and * re-acquires it afterwards. * * If return value is 0, pkt was accepted, -1 otherwise * rval is set to appropriate sata_scsi_start return value. * * Note 1:If HBA driver returns value other than TRAN_ACCEPT, it should not * have called the sata_pkt callback function for this packet. * * The scsi callback has to be performed by the caller of this routine. * * Note 2: No port multiplier support for now. */ static int sata_hba_start(sata_pkt_txlate_t *spx, int *rval) { int stat; sata_hba_inst_t *sata_hba_inst = spx->txlt_sata_hba_inst; sata_drive_info_t *sdinfo; sata_device_t sata_device; uint8_t cmd; struct sata_cmd_flags cmd_flags; ASSERT(spx->txlt_sata_pkt != NULL); ASSERT(mutex_owned(&SATA_CPORT_MUTEX(spx->txlt_sata_hba_inst, spx->txlt_sata_pkt->satapkt_device.satadev_addr.cport))); sdinfo = sata_get_device_info(sata_hba_inst, &spx->txlt_sata_pkt->satapkt_device); ASSERT(sdinfo != NULL); /* Clear device reset state? */ if (sdinfo->satadrv_event_flags & SATA_EVNT_CLEAR_DEVICE_RESET) { spx->txlt_sata_pkt->satapkt_cmd.satacmd_flags. sata_clear_dev_reset = B_TRUE; sdinfo->satadrv_event_flags &= ~SATA_EVNT_CLEAR_DEVICE_RESET; SATADBG1(SATA_DBG_EVENTS, sata_hba_inst, "sata_hba_start: clearing device reset state\n", NULL); } cmd = spx->txlt_sata_pkt->satapkt_cmd.satacmd_cmd_reg; cmd_flags = spx->txlt_sata_pkt->satapkt_cmd.satacmd_flags; sata_device = spx->txlt_sata_pkt->satapkt_device; /* local copy */ mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sdinfo->satadrv_addr.cport))); SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "Sata cmd 0x%2x\n", cmd); stat = (*SATA_START_FUNC(sata_hba_inst))(SATA_DIP(sata_hba_inst), spx->txlt_sata_pkt); mutex_enter(&(SATA_CPORT_MUTEX(sata_hba_inst, sdinfo->satadrv_addr.cport))); /* * If sata pkt was accepted and executed in asynchronous mode, i.e. * with the sata callback, the sata_pkt could be already destroyed * by the time we check ther return status from the hba_start() * function, because sata_scsi_destroy_pkt() could have been already * called (perhaps in the interrupt context). So, in such case, there * should be no references to it. In other cases, sata_pkt still * exists. */ switch (stat) { case SATA_TRAN_ACCEPTED: /* * pkt accepted for execution. * If it was executed synchronously, it is already completed * and pkt completion_reason indicates completion status. */ *rval = TRAN_ACCEPT; return (0); case SATA_TRAN_QUEUE_FULL: /* * Controller detected queue full condition. */ SATADBG1(SATA_DBG_HBA_IF, sata_hba_inst, "sata_hba_start: queue full\n", NULL); spx->txlt_scsi_pkt->pkt_reason = CMD_INCOMPLETE; *spx->txlt_scsi_pkt->pkt_scbp = STATUS_QFULL; *rval = TRAN_BUSY; break; case SATA_TRAN_PORT_ERROR: /* * Communication/link with device or general port error * detected before pkt execution begun. */ if (spx->txlt_sata_pkt->satapkt_device.satadev_addr.qual == SATA_ADDR_CPORT) sata_log(sata_hba_inst, CE_CONT, "port %d error", sata_device.satadev_addr.cport); else sata_log(sata_hba_inst, CE_CONT, "port %d pmport %d error\n", sata_device.satadev_addr.cport, sata_device.satadev_addr.pmport); /* * Update the port/device structure. * sata_pkt should be still valid. Since port error is * returned, sata_device content should reflect port * state - it means, that sata address have been changed, * because original packet's sata address refered to a device * attached to some port. */ sata_update_port_info(sata_hba_inst, &sata_device); spx->txlt_scsi_pkt->pkt_reason = CMD_TRAN_ERR; *rval = TRAN_FATAL_ERROR; break; case SATA_TRAN_CMD_UNSUPPORTED: /* * Command rejected by HBA as unsupported. It was HBA driver * that rejected the command, command was not sent to * an attached device. */ mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sdinfo->satadrv_addr.cport))); (void) sata_txlt_invalid_command(spx); mutex_enter(&(SATA_CPORT_MUTEX(sata_hba_inst, sdinfo->satadrv_addr.cport))); if (sdinfo->satadrv_state & SATA_DSTATE_RESET) SATADBG1(SATA_DBG_EVENTS, sata_hba_inst, "sat_hba_start: cmd 0x%2x rejected " "with SATA_TRAN_CMD_UNSUPPORTED status\n", cmd); *rval = TRAN_ACCEPT; break; case SATA_TRAN_BUSY: /* * Command rejected by HBA because other operation prevents * accepting the packet, or device is in RESET condition. */ if (sdinfo != NULL) { sdinfo->satadrv_state = spx->txlt_sata_pkt->satapkt_device.satadev_state; if (sdinfo->satadrv_state & SATA_DSTATE_RESET) { SATADBG1(SATA_DBG_EVENTS, sata_hba_inst, "sata_hba_start: cmd 0x%2x rejected " "because of device reset condition\n", cmd); } else { SATADBG1(SATA_DBG_EVENTS, sata_hba_inst, "sata_hba_start: cmd 0x%2x rejected " "with SATA_TRAN_BUSY status\n", cmd); } } spx->txlt_scsi_pkt->pkt_reason = CMD_INCOMPLETE; *rval = TRAN_BUSY; break; default: /* Unrecognized HBA response */ SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_hba_start: unrecognized HBA response " "to cmd : 0x%2x resp 0x%x", cmd, rval)); spx->txlt_scsi_pkt->pkt_reason = CMD_TRAN_ERR; *rval = TRAN_FATAL_ERROR; break; } /* * If we got here, the packet was rejected. * Check if we need to remember reset state clearing request */ if (cmd_flags.sata_clear_dev_reset) { /* * Check if device is still configured - it may have * disapeared from the configuration */ sdinfo = sata_get_device_info(sata_hba_inst, &sata_device); if (sdinfo != NULL) { /* * Restore the flag that requests clearing of * the device reset state, * so the next sata packet may carry it to HBA. */ sdinfo->satadrv_event_flags |= SATA_EVNT_CLEAR_DEVICE_RESET; } } return (-1); } /* * Scsi response setup for invalid LBA * * Returns TRAN_ACCEPT and appropriate values in scsi_pkt fields. */ static int sata_txlt_lba_out_of_range(sata_pkt_txlate_t *spx) { struct scsi_pkt *scsipkt = spx->txlt_scsi_pkt; struct scsi_extended_sense *sense; scsipkt->pkt_reason = CMD_CMPLT; scsipkt->pkt_state = STATE_GOT_BUS | STATE_GOT_TARGET | STATE_SENT_CMD | STATE_GOT_STATUS; *scsipkt->pkt_scbp = STATUS_CHECK; *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); sense->es_key = KEY_ILLEGAL_REQUEST; sense->es_add_code = SD_SCSI_LBA_OUT_OF_RANGE; SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "Scsi_pkt completion reason %x\n", scsipkt->pkt_reason); if ((scsipkt->pkt_flags & FLAG_NOINTR) == 0 && scsipkt->pkt_comp != NULL) /* scsi callback required */ (*scsipkt->pkt_comp)(scsipkt); return (TRAN_ACCEPT); } /* * Analyze device status and error registers and translate them into * appropriate scsi sense codes. * NOTE: non-packet commands only for now */ static void sata_decode_device_error(sata_pkt_txlate_t *spx, struct scsi_extended_sense *sense) { uint8_t err_reg = spx->txlt_sata_pkt->satapkt_cmd.satacmd_error_reg; ASSERT(sense != NULL); ASSERT(spx->txlt_sata_pkt->satapkt_cmd.satacmd_status_reg & SATA_STATUS_ERR); if (err_reg & SATA_ERROR_ICRC) { sense->es_key = KEY_ABORTED_COMMAND; sense->es_add_code = 0x08; /* Communication failure */ return; } if (err_reg & SATA_ERROR_UNC) { sense->es_key = KEY_MEDIUM_ERROR; /* Information bytes (LBA) need to be set by a caller */ return; } /* ADD HERE: MC error bit handling for ATAPI CD/DVD */ if (err_reg & (SATA_ERROR_MCR | SATA_ERROR_NM)) { sense->es_key = KEY_UNIT_ATTENTION; sense->es_add_code = 0x3a; /* No media present */ return; } if (err_reg & SATA_ERROR_IDNF) { if (err_reg & SATA_ERROR_ABORT) { sense->es_key = KEY_ABORTED_COMMAND; } else { sense->es_key = KEY_ILLEGAL_REQUEST; sense->es_add_code = 0x21; /* LBA out of range */ } return; } if (err_reg & SATA_ERROR_ABORT) { ASSERT(spx->txlt_sata_pkt != NULL); sense->es_key = KEY_ABORTED_COMMAND; return; } } /* * Extract error LBA from sata_pkt.satapkt_cmd register fields */ static void sata_extract_error_lba(sata_pkt_txlate_t *spx, uint64_t *lba) { sata_cmd_t *sata_cmd = &spx->txlt_sata_pkt->satapkt_cmd; *lba = 0; if (sata_cmd->satacmd_addr_type == ATA_ADDR_LBA48) { *lba = sata_cmd->satacmd_lba_high_msb; *lba = (*lba << 8) | sata_cmd->satacmd_lba_mid_msb; *lba = (*lba << 8) | sata_cmd->satacmd_lba_low_msb; } else if (sata_cmd->satacmd_addr_type == ATA_ADDR_LBA28) { *lba = sata_cmd->satacmd_device_reg & 0xf; } *lba = (*lba << 8) | sata_cmd->satacmd_lba_high_lsb; *lba = (*lba << 8) | sata_cmd->satacmd_lba_mid_lsb; *lba = (*lba << 8) | sata_cmd->satacmd_lba_high_lsb; } /* * This is fixed sense format - if LBA exceeds the info field size, * no valid info will be returned (valid bit in extended sense will * be set to 0). */ static struct scsi_extended_sense * sata_arq_sense(sata_pkt_txlate_t *spx) { struct scsi_pkt *scsipkt = spx->txlt_scsi_pkt; struct scsi_arq_status *arqs; struct scsi_extended_sense *sense; /* Fill ARQ sense data */ scsipkt->pkt_state |= STATE_ARQ_DONE; arqs = (struct scsi_arq_status *)scsipkt->pkt_scbp; *(uchar_t *)&arqs->sts_status = STATUS_CHECK; *(uchar_t *)&arqs->sts_rqpkt_status = STATUS_GOOD; arqs->sts_rqpkt_reason = CMD_CMPLT; arqs->sts_rqpkt_state = STATE_GOT_BUS | STATE_GOT_TARGET | STATE_XFERRED_DATA | STATE_SENT_CMD | STATE_GOT_STATUS; arqs->sts_rqpkt_resid = 0; sense = &arqs->sts_sensedata; bzero(sense, sizeof (struct scsi_extended_sense)); sense->es_valid = 1; /* Valid sense */ sense->es_class = 7; /* Response code 0x70 - current err */ sense->es_key = KEY_NO_SENSE; sense->es_info_1 = 0; sense->es_info_2 = 0; sense->es_info_3 = 0; sense->es_info_4 = 0; sense->es_add_len = 6; /* Additional length */ sense->es_cmd_info[0] = 0; sense->es_cmd_info[1] = 0; sense->es_cmd_info[2] = 0; sense->es_cmd_info[3] = 0; sense->es_add_code = 0; sense->es_qual_code = 0; return (sense); } /* * Translate completion status of SATA read/write commands into scsi response. * pkt completion_reason is checked to determine the completion status. * Do scsi callback if necessary. * * Note: this function may be called also for synchronously executed * commands. * This function may be used only if scsi_pkt is non-NULL. */ static void sata_txlt_rw_completion(sata_pkt_t *sata_pkt) { sata_pkt_txlate_t *spx = (sata_pkt_txlate_t *)sata_pkt->satapkt_framework_private; sata_cmd_t *scmd = &sata_pkt->satapkt_cmd; struct scsi_pkt *scsipkt = spx->txlt_scsi_pkt; struct scsi_extended_sense *sense; uint64_t lba; if (sata_pkt->satapkt_reason == SATA_PKT_COMPLETED) { /* Normal completion */ scsipkt->pkt_state = STATE_GOT_BUS | STATE_GOT_TARGET | STATE_SENT_CMD | STATE_XFERRED_DATA | STATE_GOT_STATUS; scsipkt->pkt_reason = CMD_CMPLT; *scsipkt->pkt_scbp = STATUS_GOOD; } else { /* * Something went wrong - analyze return */ scsipkt->pkt_state = STATE_GOT_BUS | STATE_GOT_TARGET | STATE_SENT_CMD | STATE_GOT_STATUS; scsipkt->pkt_reason = CMD_INCOMPLETE; *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); ASSERT(sense != NULL); /* * SATA_PKT_DEV_ERROR is the only case where we may be able to * extract from device registers the failing LBA. */ if (sata_pkt->satapkt_reason == SATA_PKT_DEV_ERROR) { if ((scmd->satacmd_addr_type == ATA_ADDR_LBA48) && (scmd->satacmd_lba_mid_msb != 0 || scmd->satacmd_lba_high_msb != 0)) { /* * We have problem reporting this cmd LBA * in fixed sense data format, because of * the size of the scsi LBA fields. */ sense->es_valid = 0; } else { sata_extract_error_lba(spx, &lba); sense->es_info_1 = (lba & 0xFF000000) >> 24; sense->es_info_1 = (lba & 0xFF0000) >> 16; sense->es_info_1 = (lba & 0xFF00) >> 8; sense->es_info_1 = lba & 0xFF; } } else { /* Invalid extended sense info */ sense->es_valid = 0; } switch (sata_pkt->satapkt_reason) { case SATA_PKT_PORT_ERROR: /* We may want to handle DEV GONE state as well */ /* * We have no device data. Assume no data transfered. */ sense->es_key = KEY_HARDWARE_ERROR; break; case SATA_PKT_DEV_ERROR: if (sata_pkt->satapkt_cmd.satacmd_status_reg & SATA_STATUS_ERR) { /* * determine dev error reason from error * reg content */ sata_decode_device_error(spx, sense); if (sense->es_key == KEY_MEDIUM_ERROR) { switch (scmd->satacmd_cmd_reg) { case SATAC_READ_DMA: case SATAC_READ_DMA_EXT: case SATAC_READ_DMA_QUEUED: case SATAC_READ_DMA_QUEUED_EXT: case SATAC_READ_FPDMA_QUEUED: /* Unrecovered read error */ sense->es_add_code = SD_SCSI_UNREC_READ_ERROR; break; case SATAC_WRITE_DMA: case SATAC_WRITE_DMA_EXT: case SATAC_WRITE_DMA_QUEUED: case SATAC_WRITE_DMA_QUEUED_EXT: case SATAC_WRITE_FPDMA_QUEUED: /* Write error */ sense->es_add_code = SD_SCSI_WRITE_ERROR; break; default: /* Internal error */ SATA_LOG_D(( spx->txlt_sata_hba_inst, CE_WARN, "sata_txlt_rw_completion :" "internal error - invalid " "command 0x%2x", scmd->satacmd_cmd_reg)); break; } } break; } /* No extended sense key - no info available */ scsipkt->pkt_reason = CMD_INCOMPLETE; break; case SATA_PKT_TIMEOUT: /* scsipkt->pkt_reason = CMD_TIMEOUT; */ scsipkt->pkt_reason = CMD_INCOMPLETE; /* No extended sense key ? */ break; case SATA_PKT_ABORTED: scsipkt->pkt_reason = CMD_ABORTED; /* No extended sense key ? */ break; case SATA_PKT_RESET: scsipkt->pkt_reason = CMD_RESET; break; default: SATA_LOG_D((spx->txlt_sata_hba_inst, CE_WARN, "sata_txlt_rw_completion: " "invalid packet completion reason")); scsipkt->pkt_reason = CMD_TRAN_ERR; break; } } SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "Scsi_pkt completion reason %x\n", scsipkt->pkt_reason); if ((scsipkt->pkt_flags & FLAG_NOINTR) == 0 && scsipkt->pkt_comp != NULL) /* scsi callback required */ (*scsipkt->pkt_comp)(scsipkt); } /* * NON FUNCTIONAL IMPLEMENTATION. THIS IS A PLACE HOLDER. * ATAPI devices are not supported currently (are not be attached recognized * as valid devices). * Will be fixed in phase 2 of the development. */ static void sata_txlt_atapi_completion(sata_pkt_t *sata_pkt) { sata_pkt_txlate_t *spx = (sata_pkt_txlate_t *)sata_pkt->satapkt_framework_private; struct scsi_pkt *scsipkt = spx->txlt_scsi_pkt; struct scsi_arq_status *arqs; if (sata_pkt->satapkt_reason == SATA_PKT_COMPLETED) { /* Normal completion */ scsipkt->pkt_state = STATE_GOT_BUS | STATE_GOT_TARGET | STATE_SENT_CMD | STATE_XFERRED_DATA | STATE_GOT_STATUS; scsipkt->pkt_reason = CMD_CMPLT; *scsipkt->pkt_scbp = STATUS_GOOD; scsipkt->pkt_resid = 0; } else { /* * Something went wrong - analyze return */ scsipkt->pkt_state = STATE_GOT_BUS | STATE_GOT_TARGET | STATE_SENT_CMD | STATE_GOT_STATUS | STATE_ARQ_DONE; scsipkt->pkt_reason = CMD_CMPLT; arqs = (struct scsi_arq_status *)scsipkt->pkt_scbp; *(uchar_t *)&arqs->sts_status = STATUS_CHECK; *(uchar_t *)&arqs->sts_rqpkt_status = STATUS_GOOD; arqs->sts_rqpkt_reason = CMD_CMPLT; arqs->sts_rqpkt_state = STATE_GOT_BUS | STATE_GOT_TARGET | STATE_XFERRED_DATA | STATE_SENT_CMD | STATE_GOT_STATUS; arqs->sts_rqpkt_resid = 0; bcopy(sata_pkt->satapkt_cmd.satacmd_rqsense, &arqs->sts_sensedata, SATA_ATAPI_RQSENSE_LEN); } SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "Scsi_pkt completion reason %x\n", scsipkt->pkt_reason); if ((scsipkt->pkt_flags & FLAG_NOINTR) == 0 && scsipkt->pkt_comp != NULL) { /* scsi callback required */ (*scsipkt->pkt_comp)(scsipkt); } } /* * Translate completion status of non-data commands (i.e. commands returning * no data). * pkt completion_reason is checked to determine the completion status. * Do scsi callback if necessary (FLAG_NOINTR == 0) * * Note: this function may be called also for synchronously executed * commands. * This function may be used only if scsi_pkt is non-NULL. */ static void sata_txlt_nodata_cmd_completion(sata_pkt_t *sata_pkt) { sata_pkt_txlate_t *spx = (sata_pkt_txlate_t *)sata_pkt->satapkt_framework_private; struct scsi_pkt *scsipkt = spx->txlt_scsi_pkt; struct scsi_extended_sense *sense; scsipkt->pkt_state = STATE_GOT_BUS | STATE_GOT_TARGET | STATE_SENT_CMD | STATE_GOT_STATUS; if (sata_pkt->satapkt_reason == SATA_PKT_COMPLETED) { /* Normal completion */ scsipkt->pkt_reason = CMD_CMPLT; *scsipkt->pkt_scbp = STATUS_GOOD; } else { /* Something went wrong */ scsipkt->pkt_reason = CMD_INCOMPLETE; *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); switch (sata_pkt->satapkt_reason) { case SATA_PKT_PORT_ERROR: /* * We have no device data. Assume no data transfered. */ sense->es_key = KEY_HARDWARE_ERROR; break; case SATA_PKT_DEV_ERROR: if (sata_pkt->satapkt_cmd.satacmd_status_reg & SATA_STATUS_ERR) { /* * determine dev error reason from error * reg content */ sata_decode_device_error(spx, sense); break; } /* No extended sense key - no info available */ break; case SATA_PKT_TIMEOUT: /* scsipkt->pkt_reason = CMD_TIMEOUT; */ scsipkt->pkt_reason = CMD_INCOMPLETE; /* No extended sense key ? */ break; case SATA_PKT_ABORTED: scsipkt->pkt_reason = CMD_ABORTED; /* No extended sense key ? */ break; case SATA_PKT_RESET: /* pkt aborted by an explicit reset from a host */ scsipkt->pkt_reason = CMD_RESET; break; default: SATA_LOG_D((spx->txlt_sata_hba_inst, CE_WARN, "sata_txlt_nodata_cmd_completion: " "invalid packet completion reason %d", sata_pkt->satapkt_reason)); scsipkt->pkt_reason = CMD_TRAN_ERR; break; } } SATADBG1(SATA_DBG_SCSI_IF, spx->txlt_sata_hba_inst, "Scsi_pkt completion reason %x\n", scsipkt->pkt_reason); if ((scsipkt->pkt_flags & FLAG_NOINTR) == 0 && scsipkt->pkt_comp != NULL) /* scsi callback required */ (*scsipkt->pkt_comp)(scsipkt); } /* * Build Mode sense R/W recovery page * NOT IMPLEMENTED */ static int sata_build_msense_page_1(sata_drive_info_t *sdinfo, int pcntrl, uint8_t *buf) { #ifndef __lock_lint _NOTE(ARGUNUSED(sdinfo)) _NOTE(ARGUNUSED(pcntrl)) _NOTE(ARGUNUSED(buf)) #endif return (0); } /* * Build Mode sense caching page - scsi-3 implementation. * Page length distinguishes previous format from scsi-3 format. * buf must have space for 0x12 bytes. * Only DRA (disable read ahead ) and WCE (write cache enable) are changeable. * */ static int sata_build_msense_page_8(sata_drive_info_t *sdinfo, int pcntrl, uint8_t *buf) { struct mode_cache_scsi3 *page = (struct mode_cache_scsi3 *)buf; sata_id_t *sata_id = &sdinfo->satadrv_id; /* * Most of the fields are set to 0, being not supported and/or disabled */ bzero(buf, PAGELENGTH_DAD_MODE_CACHE_SCSI3); /* Saved paramters not supported */ if (pcntrl == 3) return (0); if (pcntrl == 0 || pcntrl == 2) { /* * For now treat current and default parameters as same * That may have to change, if target driver will complain */ page->mode_page.code = MODEPAGE_CACHING; /* PS = 0 */ page->mode_page.length = PAGELENGTH_DAD_MODE_CACHE_SCSI3; if ((sata_id->ai_cmdset82 & SATA_LOOK_AHEAD) && !(sata_id->ai_features85 & SATA_LOOK_AHEAD)) { page->dra = 1; /* Read Ahead disabled */ page->rcd = 1; /* Read Cache disabled */ } if ((sata_id->ai_cmdset82 & SATA_WRITE_CACHE) && (sata_id->ai_features85 & SATA_WRITE_CACHE)) page->wce = 1; /* Write Cache enabled */ } else { /* Changeable parameters */ page->mode_page.code = MODEPAGE_CACHING; page->mode_page.length = PAGELENGTH_DAD_MODE_CACHE_SCSI3; if (sata_id->ai_cmdset82 & SATA_LOOK_AHEAD) { page->dra = 1; page->rcd = 1; } if (sata_id->ai_cmdset82 & SATA_WRITE_CACHE) page->wce = 1; } return (PAGELENGTH_DAD_MODE_CACHE_SCSI3 + sizeof (struct mode_page)); } /* * Build Mode sense exception cntrl page */ static int sata_build_msense_page_1c(sata_drive_info_t *sdinfo, int pcntrl, uint8_t *buf) { struct mode_info_excpt_page *page = (struct mode_info_excpt_page *)buf; sata_id_t *sata_id = &sdinfo->satadrv_id; /* * Most of the fields are set to 0, being not supported and/or disabled */ bzero(buf, PAGELENGTH_INFO_EXCPT); page->mode_page.code = MODEPAGE_INFO_EXCPT; page->mode_page.length = PAGELENGTH_INFO_EXCPT; /* Indicate that this is page is saveable */ page->mode_page.ps = 1; /* * We will return the same data for default, current and saved page. * The only changeable bit is dexcpt and that bit is required * by the ATA specification to be preserved across power cycles. */ if (pcntrl != 1) { page->dexcpt = !(sata_id->ai_features85 & SATA_SMART_SUPPORTED); page->mrie = MRIE_ONLY_ON_REQUEST; } else page->dexcpt = 1; /* Only changeable parameter */ return (PAGELENGTH_INFO_EXCPT + sizeof (struct mode_info_excpt_page)); } /* * Build Mode sense power condition page * NOT IMPLEMENTED. */ static int sata_build_msense_page_1a(sata_drive_info_t *sdinfo, int pcntrl, uint8_t *buf) { #ifndef __lock_lint _NOTE(ARGUNUSED(sdinfo)) _NOTE(ARGUNUSED(pcntrl)) _NOTE(ARGUNUSED(buf)) #endif return (0); } /* * Process mode select caching page 8 (scsi3 format only). * Read Ahead (same as read cache) and Write Cache may be turned on and off * if these features are supported by the device. If these features are not * supported, quietly ignore them. * This function fails only if the SET FEATURE command sent to * the device fails. The page format is not varified, assuming that the * target driver operates correctly - if parameters length is too short, * we just drop the page. * Two command may be sent if both Read Cache/Read Ahead and Write Cache * setting have to be changed. * SET FEATURE command is executed synchronously, i.e. we wait here until * it is completed, regardless of the scsi pkt directives. * * Note: Mode Select Caching page RCD and DRA bits are tied together, i.e. * changing DRA will change RCD. * * More than one SATA command may be executed to perform operations specified * by mode select pages. The first error terminates further execution. * Operations performed successully are not backed-up in such case. * * Return SATA_SUCCESS if operation succeeded, SATA_FAILURE otherwise. * If operation resulted in changing device setup, dmod flag should be set to * one (1). If parameters were not changed, dmod flag should be set to 0. * Upon return, if operation required sending command to the device, the rval * should be set to the value returned by sata_hba_start. If operation * did not require device access, rval should be set to TRAN_ACCEPT. * The pagelen should be set to the length of the page. * * This function has to be called with a port mutex held. * * Returns SATA_SUCCESS if operation was successful, SATA_FAILURE otherwise. */ int sata_mode_select_page_8(sata_pkt_txlate_t *spx, struct mode_cache_scsi3 *page, int parmlen, int *pagelen, int *rval, int *dmod) { struct scsi_pkt *scsipkt = spx->txlt_scsi_pkt; sata_drive_info_t *sdinfo; sata_cmd_t *scmd = &spx->txlt_sata_pkt->satapkt_cmd; sata_id_t *sata_id; struct scsi_extended_sense *sense; int wce, dra; /* Current settings */ sdinfo = sata_get_device_info(spx->txlt_sata_hba_inst, &spx->txlt_sata_pkt->satapkt_device); sata_id = &sdinfo->satadrv_id; *dmod = 0; /* Verify parameters length. If too short, drop it */ if (PAGELENGTH_DAD_MODE_CACHE_SCSI3 + sizeof (struct mode_page) < parmlen) { *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); sense->es_key = KEY_ILLEGAL_REQUEST; sense->es_add_code = SD_SCSI_INVALID_FIELD_IN_PARAMETER_LIST; *pagelen = parmlen; *rval = TRAN_ACCEPT; return (SATA_FAILURE); } *pagelen = PAGELENGTH_DAD_MODE_CACHE_SCSI3 + sizeof (struct mode_page); /* * We can manipulate only write cache and read ahead * (read cache) setting. */ if (!(sata_id->ai_cmdset82 & SATA_LOOK_AHEAD) && !(sata_id->ai_cmdset82 & SATA_WRITE_CACHE)) { /* * None of the features is supported - ignore */ *rval = TRAN_ACCEPT; return (SATA_SUCCESS); } /* Current setting of Read Ahead (and Read Cache) */ if (sata_id->ai_features85 & SATA_LOOK_AHEAD) dra = 0; /* 0 == not disabled */ else dra = 1; /* Current setting of Write Cache */ if (sata_id->ai_features85 & SATA_WRITE_CACHE) wce = 1; else wce = 0; if (page->dra == dra && page->wce == wce && page->rcd == dra) { /* nothing to do */ *rval = TRAN_ACCEPT; return (SATA_SUCCESS); } /* * Need to flip some setting * Set-up Internal SET FEATURES command(s) */ scmd->satacmd_flags.sata_data_direction = SATA_DIR_NODATA_XFER; scmd->satacmd_addr_type = 0; scmd->satacmd_device_reg = 0; scmd->satacmd_status_reg = 0; scmd->satacmd_error_reg = 0; scmd->satacmd_cmd_reg = SATAC_SET_FEATURES; if (page->dra != dra || page->rcd != dra) { /* Need to flip read ahead setting */ if (dra == 0) /* Disable read ahead / read cache */ scmd->satacmd_features_reg = SATAC_SF_DISABLE_READ_AHEAD; else /* Enable read ahead / read cache */ scmd->satacmd_features_reg = SATAC_SF_ENABLE_READ_AHEAD; /* Transfer command to HBA */ if (sata_hba_start(spx, rval) != 0) /* * Pkt not accepted for execution. */ return (SATA_FAILURE); *dmod = 1; /* Now process return */ if (spx->txlt_sata_pkt->satapkt_reason != SATA_PKT_COMPLETED) { goto failure; /* Terminate */ } } /* Note that the packet is not removed, so it could be re-used */ if (page->wce != wce) { /* Need to flip Write Cache setting */ if (page->wce == 1) /* Enable write cache */ scmd->satacmd_features_reg = SATAC_SF_ENABLE_WRITE_CACHE; else /* Disable write cache */ scmd->satacmd_features_reg = SATAC_SF_DISABLE_WRITE_CACHE; /* Transfer command to HBA */ if (sata_hba_start(spx, rval) != 0) /* * Pkt not accepted for execution. */ return (SATA_FAILURE); *dmod = 1; /* Now process return */ if (spx->txlt_sata_pkt->satapkt_reason != SATA_PKT_COMPLETED) { goto failure; } } return (SATA_SUCCESS); failure: sata_xlate_errors(spx); return (SATA_FAILURE); } /* * Process mode select informational exceptions control page 0x1c * * The only changeable bit is dexcpt (disable exceptions). * MRIE (method of reporting informational exceptions) must be * "only on request". * * Return SATA_SUCCESS if operation succeeded, SATA_FAILURE otherwise. * If operation resulted in changing device setup, dmod flag should be set to * one (1). If parameters were not changed, dmod flag should be set to 0. * Upon return, if operation required sending command to the device, the rval * should be set to the value returned by sata_hba_start. If operation * did not require device access, rval should be set to TRAN_ACCEPT. * The pagelen should be set to the length of the page. * * This function has to be called with a port mutex held. * * Returns SATA_SUCCESS if operation was successful, SATA_FAILURE otherwise. */ static int sata_mode_select_page_1c( sata_pkt_txlate_t *spx, struct mode_info_excpt_page *page, int parmlen, int *pagelen, int *rval, int *dmod) { struct scsi_pkt *scsipkt = spx->txlt_scsi_pkt; sata_cmd_t *scmd = &spx->txlt_sata_pkt->satapkt_cmd; sata_drive_info_t *sdinfo; sata_id_t *sata_id; struct scsi_extended_sense *sense; sdinfo = sata_get_device_info(spx->txlt_sata_hba_inst, &spx->txlt_sata_pkt->satapkt_device); sata_id = &sdinfo->satadrv_id; *dmod = 0; /* Verify parameters length. If too short, drop it */ if (((PAGELENGTH_INFO_EXCPT + sizeof (struct mode_page)) < parmlen) || page->perf || page->test || (page->mrie != MRIE_ONLY_ON_REQUEST)) { *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); sense->es_key = KEY_ILLEGAL_REQUEST; sense->es_add_code = SD_SCSI_INVALID_FIELD_IN_PARAMETER_LIST; *pagelen = parmlen; *rval = TRAN_ACCEPT; return (SATA_FAILURE); } *pagelen = PAGELENGTH_INFO_EXCPT + sizeof (struct mode_page); if (! (sata_id->ai_cmdset82 & SATA_SMART_SUPPORTED)) { *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); sense->es_key = KEY_ILLEGAL_REQUEST; sense->es_add_code = SD_SCSI_INVALID_FIELD_IN_CDB; *pagelen = parmlen; *rval = TRAN_ACCEPT; return (SATA_FAILURE); } /* If already in the state requested, we are done */ if (page->dexcpt == ! (sata_id->ai_features85 & SATA_SMART_ENABLED)) { /* nothing to do */ *rval = TRAN_ACCEPT; return (SATA_SUCCESS); } scmd->satacmd_flags.sata_data_direction = SATA_DIR_NODATA_XFER; /* Build SMART_ENABLE or SMART_DISABLE command */ scmd->satacmd_addr_type = 0; /* N/A */ scmd->satacmd_lba_mid_lsb = SMART_MAGIC_VAL_1; scmd->satacmd_lba_high_lsb = SMART_MAGIC_VAL_2; scmd->satacmd_features_reg = page->dexcpt ? SATA_SMART_DISABLE_OPS : SATA_SMART_ENABLE_OPS; scmd->satacmd_device_reg = 0; /* Always device 0 */ scmd->satacmd_cmd_reg = SATAC_SMART; /* Transfer command to HBA */ if (sata_hba_start(spx, rval) != 0) /* * Pkt not accepted for execution. */ return (SATA_FAILURE); *dmod = 1; /* At least may have been modified */ /* Now process return */ if (spx->txlt_sata_pkt->satapkt_reason == SATA_PKT_COMPLETED) return (SATA_SUCCESS); /* Packet did not complete successfully */ sata_xlate_errors(spx); return (SATA_FAILURE); } /* * sata_build_lsense_page0() is used to create the * SCSI LOG SENSE page 0 (supported log pages) * * Currently supported pages are 0, 0x10, 0x2f and 0x30 * (supported log pages, self-test results, informational exceptions * and Sun vendor specific ATA SMART data). * * Takes a sata_drive_info t * and the address of a buffer * in which to create the page information. * * Returns the number of bytes valid in the buffer. */ static int sata_build_lsense_page_0(sata_drive_info_t *sdinfo, uint8_t *buf) { struct log_parameter *lpp = (struct log_parameter *)buf; uint8_t *page_ptr = (uint8_t *)lpp->param_values; int num_pages_supported = 1; /* Always have GET_SUPPORTED_LOG_PAGES */ sata_id_t *sata_id = &sdinfo->satadrv_id; lpp->param_code[0] = 0; lpp->param_code[1] = 0; lpp->param_ctrl_flags = LOG_CTRL_LP | LOG_CTRL_LBIN; *page_ptr++ = PAGE_CODE_GET_SUPPORTED_LOG_PAGES; if (sata_id->ai_cmdset82 & SATA_SMART_SUPPORTED) { if (sata_id->ai_cmdset84 & SATA_SMART_SELF_TEST_SUPPORTED) { *page_ptr++ = PAGE_CODE_SELF_TEST_RESULTS; ++num_pages_supported; } *page_ptr++ = PAGE_CODE_INFORMATION_EXCEPTIONS; ++num_pages_supported; *page_ptr++ = PAGE_CODE_SMART_READ_DATA; ++num_pages_supported; } lpp->param_len = num_pages_supported; return ((&lpp->param_values[0] - (uint8_t *)lpp) + num_pages_supported); } /* * sata_build_lsense_page_10() is used to create the * SCSI LOG SENSE page 0x10 (self-test results) * * Takes a sata_drive_info t * and the address of a buffer * in which to create the page information as well as a sata_hba_inst_t *. * * Returns the number of bytes valid in the buffer. */ static int sata_build_lsense_page_10( sata_drive_info_t *sdinfo, uint8_t *buf, sata_hba_inst_t *sata_hba_inst) { struct log_parameter *lpp = (struct log_parameter *)buf; int rval; if (sdinfo->satadrv_features_support & SATA_DEV_F_LBA48) { struct smart_ext_selftest_log *ext_selftest_log; ext_selftest_log = kmem_zalloc( sizeof (struct smart_ext_selftest_log), KM_SLEEP); rval = sata_ext_smart_selftest_read_log(sata_hba_inst, sdinfo, ext_selftest_log, 0); if (rval == 0) { int index; struct smart_ext_selftest_log_entry *entry; uint16_t block_num; int count; index = ext_selftest_log-> smart_ext_selftest_log_index[0]; index |= ext_selftest_log-> smart_ext_selftest_log_index[1] << 8; if (index == 0) goto out; --index; /* Correct for 0 origin */ block_num = index / ENTRIES_PER_EXT_SELFTEST_LOG_BLK; if (block_num != 0) { rval = sata_ext_smart_selftest_read_log( sata_hba_inst, sdinfo, ext_selftest_log, block_num); if (rval != 0) goto out; } index %= ENTRIES_PER_EXT_SELFTEST_LOG_BLK; entry = &ext_selftest_log-> smart_ext_selftest_log_entries[index]; for (count = 1; count <= SCSI_ENTRIES_IN_LOG_SENSE_SELFTEST_RESULTS; ++count) { uint8_t status; uint8_t code; uint8_t sense_key; uint8_t add_sense_code; uint8_t add_sense_code_qual; lpp->param_code[0] = 0; lpp->param_code[1] = count; lpp->param_ctrl_flags = 0; lpp->param_len = SCSI_LOG_SENSE_SELFTEST_PARAM_LEN; status = entry->smart_ext_selftest_log_status; status >>= 4; switch (status) { case 0: default: sense_key = KEY_NO_SENSE; add_sense_code = SD_SCSI_NO_ADD_SENSE; add_sense_code_qual = 0; break; case 1: sense_key = KEY_ABORTED_COMMAND; add_sense_code = DIAGNOSTIC_FAILURE_ON_COMPONENT; add_sense_code_qual = SCSI_COMPONENT_81; break; case 2: sense_key = KEY_ABORTED_COMMAND; add_sense_code = DIAGNOSTIC_FAILURE_ON_COMPONENT; add_sense_code_qual = SCSI_COMPONENT_82; break; case 3: sense_key = KEY_ABORTED_COMMAND; add_sense_code = DIAGNOSTIC_FAILURE_ON_COMPONENT; add_sense_code_qual = SCSI_COMPONENT_83; break; case 4: sense_key = KEY_HARDWARE_ERROR; add_sense_code = DIAGNOSTIC_FAILURE_ON_COMPONENT; add_sense_code_qual = SCSI_COMPONENT_84; break; case 5: sense_key = KEY_HARDWARE_ERROR; add_sense_code = DIAGNOSTIC_FAILURE_ON_COMPONENT; add_sense_code_qual = SCSI_COMPONENT_85; break; case 6: sense_key = KEY_HARDWARE_ERROR; add_sense_code = DIAGNOSTIC_FAILURE_ON_COMPONENT; add_sense_code_qual = SCSI_COMPONENT_86; break; case 7: sense_key = KEY_MEDIUM_ERROR; add_sense_code = DIAGNOSTIC_FAILURE_ON_COMPONENT; add_sense_code_qual = SCSI_COMPONENT_87; break; case 8: sense_key = KEY_HARDWARE_ERROR; add_sense_code = DIAGNOSTIC_FAILURE_ON_COMPONENT; add_sense_code_qual = SCSI_COMPONENT_88; break; } code = 0; /* unspecified */ status |= (code << 4); lpp->param_values[0] = status; lpp->param_values[1] = 0; /* unspecified */ lpp->param_values[2] = entry-> smart_ext_selftest_log_timestamp[1]; lpp->param_values[3] = entry-> smart_ext_selftest_log_timestamp[0]; lpp->param_values[4] = 0; lpp->param_values[5] = 0; lpp->param_values[6] = entry-> smart_ext_selftest_log_failing_lba[5]; lpp->param_values[7] = entry-> smart_ext_selftest_log_failing_lba[4]; lpp->param_values[8] = entry-> smart_ext_selftest_log_failing_lba[3]; lpp->param_values[9] = entry-> smart_ext_selftest_log_failing_lba[2]; lpp->param_values[10] = entry-> smart_ext_selftest_log_failing_lba[1]; lpp->param_values[11] = entry-> smart_ext_selftest_log_failing_lba[0]; lpp->param_values[12] = sense_key; lpp->param_values[13] = add_sense_code; lpp->param_values[14] = add_sense_code_qual; lpp->param_values[15] = 0; /* undefined */ lpp = (struct log_parameter *) (((uint8_t *)lpp) + SCSI_LOG_PARAM_HDR_LEN + SCSI_LOG_SENSE_SELFTEST_PARAM_LEN); --index; /* Back up to previous entry */ if (index < 0) { if (block_num > 0) { --block_num; } else { struct read_log_ext_directory logdir; rval = sata_read_log_ext_directory( sata_hba_inst, sdinfo, &logdir); if (rval == -1) goto out; if ((logdir.read_log_ext_vers [0] == 0) && (logdir.read_log_ext_vers [1] == 0)) goto out; block_num = logdir.read_log_ext_nblks[0] [EXT_SMART_SELFTEST_LOG_PAGE - 1]; block_num |= logdir. read_log_ext_nblks[1] [EXT_SMART_SELFTEST_LOG_PAGE - 1] << 8; --block_num; } rval = sata_ext_smart_selftest_read_log( sata_hba_inst, sdinfo, ext_selftest_log, block_num); if (rval != 0) goto out; index = ENTRIES_PER_EXT_SELFTEST_LOG_BLK - 1; } index %= ENTRIES_PER_EXT_SELFTEST_LOG_BLK; entry = &ext_selftest_log-> smart_ext_selftest_log_entries[index]; } } out: kmem_free(ext_selftest_log, sizeof (struct smart_ext_selftest_log)); } else { struct smart_selftest_log *selftest_log; selftest_log = kmem_zalloc(sizeof (struct smart_selftest_log), KM_SLEEP); rval = sata_smart_selftest_log(sata_hba_inst, sdinfo, selftest_log); if (rval == 0) { int index; int count; struct smart_selftest_log_entry *entry; index = selftest_log->smart_selftest_log_index; if (index == 0) goto done; --index; /* Correct for 0 origin */ entry = &selftest_log-> smart_selftest_log_entries[index]; for (count = 1; count <= SCSI_ENTRIES_IN_LOG_SENSE_SELFTEST_RESULTS; ++count) { uint8_t status; uint8_t code; uint8_t sense_key; uint8_t add_sense_code; uint8_t add_sense_code_qual; lpp->param_code[0] = 0; lpp->param_code[1] = count; lpp->param_ctrl_flags = 0; lpp->param_len = SCSI_LOG_SENSE_SELFTEST_PARAM_LEN; status = entry->smart_selftest_log_status; status >>= 4; switch (status) { case 0: default: sense_key = KEY_NO_SENSE; add_sense_code = SD_SCSI_NO_ADD_SENSE; break; case 1: sense_key = KEY_ABORTED_COMMAND; add_sense_code = DIAGNOSTIC_FAILURE_ON_COMPONENT; add_sense_code_qual = SCSI_COMPONENT_81; break; case 2: sense_key = KEY_ABORTED_COMMAND; add_sense_code = DIAGNOSTIC_FAILURE_ON_COMPONENT; add_sense_code_qual = SCSI_COMPONENT_82; break; case 3: sense_key = KEY_ABORTED_COMMAND; add_sense_code = DIAGNOSTIC_FAILURE_ON_COMPONENT; add_sense_code_qual = SCSI_COMPONENT_83; break; case 4: sense_key = KEY_HARDWARE_ERROR; add_sense_code = DIAGNOSTIC_FAILURE_ON_COMPONENT; add_sense_code_qual = SCSI_COMPONENT_84; break; case 5: sense_key = KEY_HARDWARE_ERROR; add_sense_code = DIAGNOSTIC_FAILURE_ON_COMPONENT; add_sense_code_qual = SCSI_COMPONENT_85; break; case 6: sense_key = KEY_HARDWARE_ERROR; add_sense_code = DIAGNOSTIC_FAILURE_ON_COMPONENT; add_sense_code_qual = SCSI_COMPONENT_86; break; case 7: sense_key = KEY_MEDIUM_ERROR; add_sense_code = DIAGNOSTIC_FAILURE_ON_COMPONENT; add_sense_code_qual = SCSI_COMPONENT_87; break; case 8: sense_key = KEY_HARDWARE_ERROR; add_sense_code = DIAGNOSTIC_FAILURE_ON_COMPONENT; add_sense_code_qual = SCSI_COMPONENT_88; break; } code = 0; /* unspecified */ status |= (code << 4); lpp->param_values[0] = status; lpp->param_values[1] = 0; /* unspecified */ lpp->param_values[2] = entry-> smart_selftest_log_timestamp[1]; lpp->param_values[3] = entry-> smart_selftest_log_timestamp[0]; lpp->param_values[4] = 0; lpp->param_values[5] = 0; lpp->param_values[6] = 0; lpp->param_values[7] = 0; lpp->param_values[8] = entry-> smart_selftest_log_failing_lba[3]; lpp->param_values[9] = entry-> smart_selftest_log_failing_lba[2]; lpp->param_values[10] = entry-> smart_selftest_log_failing_lba[1]; lpp->param_values[11] = entry-> smart_selftest_log_failing_lba[0]; lpp->param_values[12] = sense_key; lpp->param_values[13] = add_sense_code; lpp->param_values[14] = add_sense_code_qual; lpp->param_values[15] = 0; /* undefined */ lpp = (struct log_parameter *) (((uint8_t *)lpp) + SCSI_LOG_PARAM_HDR_LEN + SCSI_LOG_SENSE_SELFTEST_PARAM_LEN); --index; /* back up to previous entry */ if (index < 0) { index = NUM_SMART_SELFTEST_LOG_ENTRIES - 1; } entry = &selftest_log-> smart_selftest_log_entries[index]; } } done: kmem_free(selftest_log, sizeof (struct smart_selftest_log)); } return ((SCSI_LOG_PARAM_HDR_LEN + SCSI_LOG_SENSE_SELFTEST_PARAM_LEN) * SCSI_ENTRIES_IN_LOG_SENSE_SELFTEST_RESULTS); } /* * sata_build_lsense_page_2f() is used to create the * SCSI LOG SENSE page 0x10 (informational exceptions) * * Takes a sata_drive_info t * and the address of a buffer * in which to create the page information as well as a sata_hba_inst_t *. * * Returns the number of bytes valid in the buffer. */ static int sata_build_lsense_page_2f( sata_drive_info_t *sdinfo, uint8_t *buf, sata_hba_inst_t *sata_hba_inst) { struct log_parameter *lpp = (struct log_parameter *)buf; int rval; uint8_t *smart_data; uint8_t temp; sata_id_t *sata_id; #define SMART_NO_TEMP 0xff lpp->param_code[0] = 0; lpp->param_code[1] = 0; lpp->param_ctrl_flags = LOG_CTRL_LP | LOG_CTRL_LBIN; /* Now get the SMART status w.r.t. threshold exceeded */ rval = sata_fetch_smart_return_status(sata_hba_inst, sdinfo); switch (rval) { case 1: lpp->param_values[0] = SCSI_PREDICTED_FAILURE; lpp->param_values[1] = SCSI_GENERAL_HD_FAILURE; break; case 0: case -1: /* failed to get data */ lpp->param_values[0] = 0; lpp->param_values[1] = 0; break; #if defined(SATA_DEBUG) default: cmn_err(CE_PANIC, "sata_build_lsense_page_2f bad return value"); /* NOTREACHED */ #endif } sata_id = &sdinfo->satadrv_id; if (! (sata_id->ai_sctsupport & SATA_SCT_CMD_TRANS_SUP)) temp = SMART_NO_TEMP; else { /* Now get the temperature */ smart_data = kmem_zalloc(512, KM_SLEEP); rval = sata_smart_read_log(sata_hba_inst, sdinfo, smart_data, SCT_STATUS_LOG_PAGE, 1); if (rval == -1) temp = SMART_NO_TEMP; else { temp = smart_data[200]; if (temp & 0x80) { if (temp & 0x7f) temp = 0; else temp = SMART_NO_TEMP; } } kmem_free(smart_data, 512); } lpp->param_values[2] = temp; lpp->param_len = SCSI_INFO_EXCEPTIONS_PARAM_LEN; return (SCSI_INFO_EXCEPTIONS_PARAM_LEN + SCSI_LOG_PARAM_HDR_LEN); } /* * sata_build_lsense_page_30() is used to create the * SCSI LOG SENSE page 0x30 (Sun's vendor specific page for ATA SMART data). * * Takes a sata_drive_info t * and the address of a buffer * in which to create the page information as well as a sata_hba_inst_t *. * * Returns the number of bytes valid in the buffer. */ static int sata_build_lsense_page_30( sata_drive_info_t *sdinfo, uint8_t *buf, sata_hba_inst_t *sata_hba_inst) { struct smart_data *smart_data = (struct smart_data *)buf; int rval; /* Now do the SMART READ DATA */ rval = sata_fetch_smart_data(sata_hba_inst, sdinfo, smart_data); if (rval == -1) return (0); return (sizeof (struct smart_data)); } /* ************************** LOCAL FUNCTIONS ************************** */ /* * Validate sata_tran info * SATA_FAILURE returns if structure is inconsistent or structure revision * does not match one used by the framework. * * Returns SATA_SUCCESS if sata_hba_tran has matching revision and contains * required function pointers. * Returns SATA_FAILURE otherwise. */ static int sata_validate_sata_hba_tran(dev_info_t *dip, sata_hba_tran_t *sata_tran) { if (sata_tran->sata_tran_hba_rev != SATA_TRAN_HBA_REV) { sata_log(NULL, CE_WARN, "sata: invalid sata_hba_tran version %d for driver %s", sata_tran->sata_tran_hba_rev, ddi_driver_name(dip)); return (SATA_FAILURE); } if (dip != sata_tran->sata_tran_hba_dip) { SATA_LOG_D((NULL, CE_WARN, "sata: inconsistent sata_tran_hba_dip " "%p / %p", sata_tran->sata_tran_hba_dip, dip)); return (SATA_FAILURE); } if (sata_tran->sata_tran_probe_port == NULL || sata_tran->sata_tran_start == NULL || sata_tran->sata_tran_abort == NULL || sata_tran->sata_tran_reset_dport == NULL) { SATA_LOG_D((NULL, CE_WARN, "sata: sata_hba_tran missing " "required functions")); } return (SATA_SUCCESS); } /* * Remove HBA instance from sata_hba_list. */ static void sata_remove_hba_instance(dev_info_t *dip) { sata_hba_inst_t *sata_hba_inst; mutex_enter(&sata_mutex); for (sata_hba_inst = sata_hba_list; sata_hba_inst != (struct sata_hba_inst *)NULL; sata_hba_inst = sata_hba_inst->satahba_next) { if (sata_hba_inst->satahba_dip == dip) break; } if (sata_hba_inst == (struct sata_hba_inst *)NULL) { #ifdef SATA_DEBUG cmn_err(CE_WARN, "sata_remove_hba_instance: " "unknown HBA instance\n"); #endif ASSERT(FALSE); } if (sata_hba_inst == sata_hba_list) { sata_hba_list = sata_hba_inst->satahba_next; if (sata_hba_list) { sata_hba_list->satahba_prev = (struct sata_hba_inst *)NULL; } if (sata_hba_inst == sata_hba_list_tail) { sata_hba_list_tail = NULL; } } else if (sata_hba_inst == sata_hba_list_tail) { sata_hba_list_tail = sata_hba_inst->satahba_prev; if (sata_hba_list_tail) { sata_hba_list_tail->satahba_next = (struct sata_hba_inst *)NULL; } } else { sata_hba_inst->satahba_prev->satahba_next = sata_hba_inst->satahba_next; sata_hba_inst->satahba_next->satahba_prev = sata_hba_inst->satahba_prev; } mutex_exit(&sata_mutex); } /* * Probe all SATA ports of the specified HBA instance. * This function is called only from sata_hba_attach(). It does not have to * be protected by controller mutex, because the hba_attached flag is not set * yet and no one would be touching this HBA instance other then this thread. * Determines if port is active and what type of the device is attached * (if any). Allocates necessary structures for each port. * Creates attachment point minor node for each non-failed port. */ static void sata_probe_ports(sata_hba_inst_t *sata_hba_inst) { dev_info_t *dip = SATA_DIP(sata_hba_inst); int ncport, npmport; sata_cport_info_t *cportinfo; sata_drive_info_t *drive; sata_pmult_info_t *pminfo; sata_pmport_info_t *pmportinfo; sata_device_t sata_device; int rval; dev_t minor_number; char name[16]; /* * Probe controller ports first, to find port status and * any port multiplier attached. */ for (ncport = 0; ncport < SATA_NUM_CPORTS(sata_hba_inst); ncport++) { /* allocate cport structure */ cportinfo = kmem_zalloc(sizeof (sata_cport_info_t), KM_SLEEP); ASSERT(cportinfo != NULL); mutex_init(&cportinfo->cport_mutex, NULL, MUTEX_DRIVER, NULL); mutex_enter(&cportinfo->cport_mutex); cportinfo->cport_addr.cport = ncport; cportinfo->cport_addr.pmport = 0; cportinfo->cport_addr.qual = SATA_ADDR_CPORT; cportinfo->cport_state &= ~SATA_PORT_STATE_CLEAR_MASK; cportinfo->cport_state |= SATA_STATE_PROBING; SATA_CPORT_INFO(sata_hba_inst, ncport) = cportinfo; /* * Regardless if a port is usable or not, create * an attachment point */ mutex_exit(&cportinfo->cport_mutex); minor_number = SATA_MAKE_AP_MINOR(ddi_get_instance(dip), ncport, 0, 0); (void) sprintf(name, "%d", ncport); if (ddi_create_minor_node(dip, name, S_IFCHR, minor_number, DDI_NT_SATA_ATTACHMENT_POINT, 0) != DDI_SUCCESS) { sata_log(sata_hba_inst, CE_WARN, "sata_hba_attach: " "cannot create sata attachment point for port %d", ncport); } /* Probe port */ sata_device.satadev_addr.cport = ncport; sata_device.satadev_addr.pmport = 0; sata_device.satadev_addr.qual = SATA_ADDR_CPORT; sata_device.satadev_rev = SATA_DEVICE_REV; rval = (*SATA_PROBE_PORT_FUNC(sata_hba_inst)) (dip, &sata_device); mutex_enter(&cportinfo->cport_mutex); sata_update_port_scr(&cportinfo->cport_scr, &sata_device); if (rval != SATA_SUCCESS) { /* Something went wrong? Fail the port */ cportinfo->cport_state = SATA_PSTATE_FAILED; mutex_exit(&cportinfo->cport_mutex); continue; } cportinfo->cport_state &= ~SATA_STATE_PROBING; cportinfo->cport_state |= SATA_STATE_PROBED; cportinfo->cport_dev_type = sata_device.satadev_type; cportinfo->cport_state |= SATA_STATE_READY; if (cportinfo->cport_dev_type == SATA_DTYPE_NONE) { mutex_exit(&cportinfo->cport_mutex); continue; } if (cportinfo->cport_dev_type != SATA_DTYPE_PMULT) { /* * There is some device attached. * Allocate device info structure */ mutex_exit(&cportinfo->cport_mutex); drive = kmem_zalloc(sizeof (sata_drive_info_t), KM_SLEEP); mutex_enter(&cportinfo->cport_mutex); SATA_CPORTINFO_DRV_INFO(cportinfo) = drive; drive->satadrv_addr = cportinfo->cport_addr; drive->satadrv_addr.qual = SATA_ADDR_DCPORT; drive->satadrv_type = cportinfo->cport_dev_type; drive->satadrv_state = SATA_STATE_UNKNOWN; } else { ASSERT(cportinfo->cport_dev_type == SATA_DTYPE_PMULT); mutex_exit(&cportinfo->cport_mutex); pminfo = kmem_zalloc(sizeof (sata_pmult_info_t), KM_SLEEP); mutex_enter(&cportinfo->cport_mutex); ASSERT(pminfo != NULL); SATA_CPORTINFO_PMULT_INFO(cportinfo) = pminfo; pminfo->pmult_addr.cport = cportinfo->cport_addr.cport; pminfo->pmult_addr.pmport = SATA_PMULT_HOSTPORT; pminfo->pmult_addr.qual = SATA_ADDR_PMPORT; pminfo->pmult_num_dev_ports = sata_device.satadev_add_info; mutex_init(&pminfo->pmult_mutex, NULL, MUTEX_DRIVER, NULL); pminfo->pmult_state = SATA_STATE_PROBING; /* Probe Port Multiplier ports */ for (npmport = 0; npmport < pminfo->pmult_num_dev_ports; npmport++) { mutex_exit(&cportinfo->cport_mutex); pmportinfo = kmem_zalloc( sizeof (sata_pmport_info_t), KM_SLEEP); mutex_enter(&cportinfo->cport_mutex); ASSERT(pmportinfo != NULL); pmportinfo->pmport_addr.cport = ncport; pmportinfo->pmport_addr.pmport = npmport; pmportinfo->pmport_addr.qual = SATA_ADDR_PMPORT; pminfo->pmult_dev_port[npmport] = pmportinfo; mutex_init(&pmportinfo->pmport_mutex, NULL, MUTEX_DRIVER, NULL); sata_device.satadev_addr.pmport = npmport; sata_device.satadev_addr.qual = SATA_ADDR_PMPORT; mutex_exit(&cportinfo->cport_mutex); /* Create an attachment point */ minor_number = SATA_MAKE_AP_MINOR( ddi_get_instance(dip), ncport, npmport, 1); (void) sprintf(name, "%d.%d", ncport, npmport); if (ddi_create_minor_node(dip, name, S_IFCHR, minor_number, DDI_NT_SATA_ATTACHMENT_POINT, 0) != DDI_SUCCESS) { sata_log(sata_hba_inst, CE_WARN, "sata_hba_attach: " "cannot create sata attachment " "point for port %d pmult port %d", ncport, npmport); } rval = (*SATA_PROBE_PORT_FUNC(sata_hba_inst)) (dip, &sata_device); mutex_enter(&cportinfo->cport_mutex); /* sata_update_port_info() */ sata_update_port_scr(&pmportinfo->pmport_scr, &sata_device); if (rval != SATA_SUCCESS) { pmportinfo->pmport_state = SATA_PSTATE_FAILED; continue; } pmportinfo->pmport_state &= ~SATA_STATE_PROBING; pmportinfo->pmport_state |= SATA_STATE_PROBED; pmportinfo->pmport_dev_type = sata_device.satadev_type; pmportinfo->pmport_state |= SATA_STATE_READY; if (pmportinfo->pmport_dev_type == SATA_DTYPE_NONE) continue; /* Port multipliers cannot be chained */ ASSERT(pmportinfo->pmport_dev_type != SATA_DTYPE_PMULT); /* * There is something attached to Port * Multiplier device port * Allocate device info structure */ mutex_exit(&cportinfo->cport_mutex); drive = kmem_zalloc( sizeof (sata_drive_info_t), KM_SLEEP); rval = (*SATA_PROBE_PORT_FUNC(sata_hba_inst)) (dip, &sata_device); mutex_enter(&cportinfo->cport_mutex); /* sata_update_port_info() */ sata_update_port_scr(&pmportinfo->pmport_scr, &sata_device); pmportinfo->pmport_sata_drive = drive; drive->satadrv_addr.cport = pmportinfo->pmport_addr.cport; drive->satadrv_addr.pmport = npmport; drive->satadrv_addr.qual = SATA_ADDR_DPMPORT; drive->satadrv_type = pmportinfo-> pmport_dev_type; drive->satadrv_state = SATA_STATE_UNKNOWN; } pmportinfo->pmport_state = SATA_STATE_PROBED | SATA_STATE_READY; } mutex_exit(&cportinfo->cport_mutex); } } /* * Create SATA device nodes for specified HBA instance (SCSI target * device nodes). * This function is called only from sata_hba_attach(). The hba_attached flag * is not set yet, so no ports or device data structures would be touched * by anyone other then this thread, therefore per-port mutex protection is * not needed. * The assumption is that there are no target and attachment point minor nodes * created by the boot subsystems, so we do not need to prune device tree. * An AP (Attachement Point) node is created for each SATA device port even * when there is no device attached. * A target node is created when there is a supported type of device attached, * but may be removed if it cannot be put online. * * This function cannot be called from an interrupt context. * * ONLY DISK TARGET NODES ARE CREATED NOW */ static void sata_make_device_nodes(dev_info_t *pdip, sata_hba_inst_t *sata_hba_inst) { int ncport, npmport; sata_cport_info_t *cportinfo; sata_pmult_info_t *pminfo; sata_pmport_info_t *pmportinfo; dev_info_t *cdip; /* child dip */ sata_device_t sata_device; int rval; /* * Walk through pre-probed sata ports info in sata_scsi */ for (ncport = 0; ncport < SATA_NUM_CPORTS(sata_hba_inst); ncport++) { cportinfo = SATA_CPORT_INFO(sata_hba_inst, ncport); mutex_enter(&cportinfo->cport_mutex); if (!(cportinfo->cport_state & SATA_STATE_PROBED)) { mutex_exit(&cportinfo->cport_mutex); continue; } if (cportinfo->cport_state == SATA_PSTATE_FAILED) { mutex_exit(&cportinfo->cport_mutex); continue; } if (cportinfo->cport_dev_type == SATA_DTYPE_NONE) { /* No device attached to the controller port */ mutex_exit(&cportinfo->cport_mutex); continue; } /* * Some device is attached to a controller port. * We rely on controllers distinquishing between no-device, * attached port multiplier and other kind of attached device. * We need to get Identify Device data and determine * positively the dev type before trying to attach * the target driver. */ sata_device.satadev_rev = SATA_DEVICE_REV; if (cportinfo->cport_dev_type != SATA_DTYPE_PMULT) { /* * Not port multiplier. */ sata_device.satadev_addr = cportinfo->cport_addr; sata_device.satadev_addr.qual = SATA_ADDR_DCPORT; mutex_exit(&cportinfo->cport_mutex); rval = sata_probe_device(sata_hba_inst, &sata_device); if (rval != SATA_SUCCESS || sata_device.satadev_type == SATA_DTYPE_UNKNOWN) continue; mutex_enter(&cportinfo->cport_mutex); sata_save_drive_settings( SATA_CPORTINFO_DRV_INFO(cportinfo)); if ((sata_device.satadev_type & SATA_VALID_DEV_TYPE) == 0) { /* * Could not determine device type or * a device is not supported. * Degrade this device to unknown. */ cportinfo->cport_dev_type = SATA_DTYPE_UNKNOWN; mutex_exit(&cportinfo->cport_mutex); continue; } cportinfo->cport_dev_type = sata_device.satadev_type; sata_show_drive_info(sata_hba_inst, SATA_CPORTINFO_DRV_INFO(cportinfo)); mutex_exit(&cportinfo->cport_mutex); cdip = sata_create_target_node(pdip, sata_hba_inst, &sata_device.satadev_addr); mutex_enter(&cportinfo->cport_mutex); if (cdip == NULL) { /* * Attaching target node failed. * We retain sata_drive_info structure... */ (SATA_CPORTINFO_DRV_INFO(cportinfo))-> satadrv_type = SATA_DTYPE_UNKNOWN; (SATA_CPORTINFO_DRV_INFO(cportinfo))-> satadrv_state = SATA_STATE_UNKNOWN; cportinfo->cport_dev_type = SATA_DTYPE_UNKNOWN; mutex_exit(&cportinfo->cport_mutex); continue; } (SATA_CPORTINFO_DRV_INFO(cportinfo))-> satadrv_state = SATA_STATE_READY; } else { /* This must be Port Multiplier type */ if (cportinfo->cport_dev_type != SATA_DTYPE_PMULT) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_make_device_nodes: " "unknown dev type %x", cportinfo->cport_dev_type)); mutex_exit(&cportinfo->cport_mutex); continue; } pminfo = SATA_CPORTINFO_PMULT_INFO(cportinfo); for (npmport = 0; npmport < pminfo->pmult_num_dev_ports; npmport++) { pmportinfo = pminfo->pmult_dev_port[npmport]; if (pmportinfo->pmport_state & SATA_PSTATE_FAILED) { continue; } if (pmportinfo->pmport_dev_type & SATA_DTYPE_NONE) /* No device attached */ continue; sata_device.satadev_addr = pmportinfo->pmport_addr; sata_device.satadev_addr.qual = SATA_ADDR_DPMPORT; mutex_exit(&cportinfo->cport_mutex); rval = sata_probe_device(sata_hba_inst, &sata_device); if (rval != SATA_SUCCESS || sata_device.satadev_type == SATA_DTYPE_UNKNOWN) { mutex_enter(&cportinfo->cport_mutex); continue; } mutex_enter(&cportinfo->cport_mutex); sata_save_drive_settings( pmportinfo->pmport_sata_drive); if ((sata_device.satadev_type & SATA_VALID_DEV_TYPE) == 0) { /* * Could not determine device type. * Degrade this device to unknown. */ pmportinfo->pmport_dev_type = SATA_DTYPE_UNKNOWN; continue; } pmportinfo->pmport_dev_type = sata_device.satadev_type; sata_show_drive_info(sata_hba_inst, pmportinfo->pmport_sata_drive); mutex_exit(&cportinfo->cport_mutex); cdip = sata_create_target_node(pdip, sata_hba_inst, &sata_device.satadev_addr); mutex_enter(&cportinfo->cport_mutex); if (cdip == NULL) { /* * Attaching target node failed. * We retain sata_drive_info * structure... */ pmportinfo->pmport_sata_drive-> satadrv_type = SATA_DTYPE_UNKNOWN; pmportinfo->pmport_sata_drive-> satadrv_state = SATA_STATE_UNKNOWN; pmportinfo->pmport_dev_type = SATA_DTYPE_UNKNOWN; continue; } pmportinfo->pmport_sata_drive-> satadrv_state |= SATA_STATE_READY; } } mutex_exit(&cportinfo->cport_mutex); } } /* * Create scsi target node for attached device, create node properties and * attach the node. * The node could be removed if the device onlining fails. * * A dev_info_t pointer is returned if operation is successful, NULL is * returned otherwise. */ static dev_info_t * sata_create_target_node(dev_info_t *dip, sata_hba_inst_t *sata_hba_inst, sata_address_t *sata_addr) { dev_info_t *cdip = NULL; int rval; char *nname = NULL; char **compatible = NULL; int ncompatible; struct scsi_inquiry inq; sata_device_t sata_device; sata_drive_info_t *sdinfo; int target; int i; sata_device.satadev_rev = SATA_DEVICE_REV; sata_device.satadev_addr = *sata_addr; mutex_enter(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_addr->cport))); sdinfo = sata_get_device_info(sata_hba_inst, &sata_device); target = SATA_TO_SCSI_TARGET(sata_addr->cport, sata_addr->pmport, sata_addr->qual); if (sdinfo == NULL) { mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_addr->cport))); SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_create_target_node: no sdinfo for target %x", target)); return (NULL); } /* * create scsi inquiry data, expected by * scsi_hba_nodename_compatible_get() */ sata_identdev_to_inquiry(sata_hba_inst, sdinfo, (uint8_t *)&inq); mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_addr->cport))); /* determine the node name and compatible */ scsi_hba_nodename_compatible_get(&inq, NULL, inq.inq_dtype, NULL, &nname, &compatible, &ncompatible); #ifdef SATA_DEBUG if (sata_debug_flags & SATA_DBG_NODES) { if (nname == NULL) { cmn_err(CE_NOTE, "sata_create_target_node: " "cannot determine nodename for target %d\n", target); } else { cmn_err(CE_WARN, "sata_create_target_node: " "target %d nodename: %s\n", target, nname); } if (compatible == NULL) { cmn_err(CE_WARN, "sata_create_target_node: no compatible name\n"); } else { for (i = 0; i < ncompatible; i++) { cmn_err(CE_WARN, "sata_create_target_node: " "compatible name: %s\n", compatible[i]); } } } #endif /* if nodename can't be determined, log error and exit */ if (nname == NULL) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_create_target_node: cannot determine nodename " "for target %d\n", target)); scsi_hba_nodename_compatible_free(nname, compatible); return (NULL); } /* * Create scsi target node */ ndi_devi_alloc_sleep(dip, nname, (pnode_t)DEVI_SID_NODEID, &cdip); rval = ndi_prop_update_string(DDI_DEV_T_NONE, cdip, "device-type", "scsi"); if (rval != DDI_PROP_SUCCESS) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_create_target_node: " "updating device_type prop failed %d", rval)); goto fail; } /* * Create target node properties: target & lun */ rval = ndi_prop_update_int(DDI_DEV_T_NONE, cdip, "target", target); if (rval != DDI_PROP_SUCCESS) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_create_target_node: " "updating target prop failed %d", rval)); goto fail; } rval = ndi_prop_update_int(DDI_DEV_T_NONE, cdip, "lun", 0); if (rval != DDI_PROP_SUCCESS) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_create_target_node: " "updating target prop failed %d", rval)); goto fail; } /* decorate the node with compatible */ if (ndi_prop_update_string_array(DDI_DEV_T_NONE, cdip, "compatible", compatible, ncompatible) != DDI_PROP_SUCCESS) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_create_target_node: FAIL compatible props cdip 0x%p", (void *)cdip)); goto fail; } /* * Now, try to attach the driver. If probing of the device fails, * the target node may be removed */ rval = ndi_devi_online(cdip, NDI_ONLINE_ATTACH); scsi_hba_nodename_compatible_free(nname, compatible); if (rval == NDI_SUCCESS) return (cdip); /* target node was removed - are we sure? */ return (NULL); fail: scsi_hba_nodename_compatible_free(nname, compatible); ddi_prop_remove_all(cdip); rval = ndi_devi_free(cdip); if (rval != NDI_SUCCESS) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_create_target_node: " "node removal failed %d", rval)); } sata_log(sata_hba_inst, CE_WARN, "sata_create_target_node: " "cannot create target node for device at port %d", sata_addr->cport); return (NULL); } /* * Re-probe sata port, check for a device and attach necessary info * structures when necessary. Identify Device data is fetched, if possible. * Assumption: sata address is already validated. * SATA_SUCCESS is returned if port is re-probed sucessfully, regardless of * the presence of a device and its type. * SATA_FAILURE is returned if one of the operations failed. */ static int sata_reprobe_port(sata_hba_inst_t *sata_hba_inst, sata_device_t *sata_device) { sata_cport_info_t *cportinfo; sata_drive_info_t *sdinfo; int rval; /* We only care about host sata cport for now */ cportinfo = SATA_CPORT_INFO(sata_hba_inst, sata_device->satadev_addr.cport); /* probe port */ mutex_enter(&cportinfo->cport_mutex); cportinfo->cport_state &= ~SATA_PORT_STATE_CLEAR_MASK; cportinfo->cport_state |= SATA_STATE_PROBING; mutex_exit(&cportinfo->cport_mutex); rval = (*SATA_PROBE_PORT_FUNC(sata_hba_inst)) (SATA_DIP(sata_hba_inst), sata_device); mutex_enter(&cportinfo->cport_mutex); if (rval != SATA_SUCCESS) { cportinfo->cport_state = SATA_PSTATE_FAILED; mutex_exit(&cportinfo->cport_mutex); SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_hba_ioctl: " "connect: port probbing failed")); return (SATA_FAILURE); } /* * update sata port state and set device type */ sata_update_port_info(sata_hba_inst, sata_device); cportinfo->cport_state |= SATA_STATE_PROBED; /* * Sanity check - Port is active? Is the link active? * Is there any device attached? */ if ((cportinfo->cport_state & (SATA_PSTATE_SHUTDOWN | SATA_PSTATE_FAILED)) || (cportinfo->cport_scr.sstatus & SATA_PORT_DEVLINK_UP_MASK) != SATA_PORT_DEVLINK_UP) { /* * Port in non-usable state or no link active/no device. * Free info structure if necessary (direct attached drive * only, for now! */ sdinfo = SATA_CPORTINFO_DRV_INFO(cportinfo); SATA_CPORTINFO_DRV_INFO(cportinfo) = NULL; /* Add here differentiation for device attached or not */ cportinfo->cport_dev_type = SATA_DTYPE_NONE; mutex_exit(&cportinfo->cport_mutex); if (sdinfo != NULL) kmem_free(sdinfo, sizeof (sata_drive_info_t)); return (SATA_SUCCESS); } cportinfo->cport_state |= SATA_STATE_READY; cportinfo->cport_dev_type = sata_device->satadev_type; sdinfo = SATA_CPORTINFO_DRV_INFO(cportinfo); /* * If we are re-probing the port, there may be * sata_drive_info structure attached * (or sata_pm_info, if PMult is supported). */ if (sata_device->satadev_type == SATA_DTYPE_NONE) { /* * There is no device, so remove device info structure, * if necessary. Direct attached drive only! */ SATA_CPORTINFO_DRV_INFO(cportinfo) = NULL; cportinfo->cport_dev_type = SATA_DTYPE_NONE; if (sdinfo != NULL) { kmem_free(sdinfo, sizeof (sata_drive_info_t)); sata_log(sata_hba_inst, CE_WARN, "SATA device detached " "from port %d", cportinfo->cport_addr.cport); } mutex_exit(&cportinfo->cport_mutex); return (SATA_SUCCESS); } if (sata_device->satadev_type != SATA_DTYPE_PMULT) { if (sdinfo == NULL) { /* * There is some device attached, but there is * no sata_drive_info structure - allocate one */ mutex_exit(&cportinfo->cport_mutex); sdinfo = kmem_zalloc( sizeof (sata_drive_info_t), KM_SLEEP); mutex_enter(&cportinfo->cport_mutex); /* * Recheck, if port state did not change when we * released mutex. */ if (cportinfo->cport_state & SATA_STATE_READY) { SATA_CPORTINFO_DRV_INFO(cportinfo) = sdinfo; sdinfo->satadrv_addr = cportinfo->cport_addr; sdinfo->satadrv_addr.qual = SATA_ADDR_DCPORT; sdinfo->satadrv_type = SATA_DTYPE_UNKNOWN; sdinfo->satadrv_state = SATA_STATE_UNKNOWN; } else { /* * Port is not in ready state, we * cannot attach a device. */ mutex_exit(&cportinfo->cport_mutex); kmem_free(sdinfo, sizeof (sata_drive_info_t)); return (SATA_SUCCESS); } } cportinfo->cport_dev_type = SATA_DTYPE_UNKNOWN; sata_device->satadev_addr.qual = sdinfo->satadrv_addr.qual; } else { cportinfo->cport_dev_type = SATA_DTYPE_UNKNOWN; mutex_exit(&cportinfo->cport_mutex); return (SATA_SUCCESS); } mutex_exit(&cportinfo->cport_mutex); /* * Figure out what kind of device we are really * dealing with. */ return (sata_probe_device(sata_hba_inst, sata_device)); } /* * Validate sata address. * Specified cport, pmport and qualifier has to match * passed sata_scsi configuration info. * The presence of an attached device is not verified. * * Returns 0 when address is valid, -1 otherwise. */ static int sata_validate_sata_address(sata_hba_inst_t *sata_hba_inst, int cport, int pmport, int qual) { if (qual == SATA_ADDR_DCPORT && pmport != 0) goto invalid_address; if (cport >= SATA_NUM_CPORTS(sata_hba_inst)) goto invalid_address; if ((qual == SATA_ADDR_DPMPORT || qual == SATA_ADDR_PMPORT) && ((SATA_CPORT_DEV_TYPE(sata_hba_inst, cport) != SATA_DTYPE_PMULT) || (SATA_PMULT_INFO(sata_hba_inst, cport) == NULL) || (pmport >= SATA_NUM_PMPORTS(sata_hba_inst, cport)))) goto invalid_address; return (0); invalid_address: return (-1); } /* * Validate scsi address * SCSI target address is translated into SATA cport/pmport and compared * with a controller port/device configuration. LUN has to be 0. * Returns 0 if a scsi target refers to an attached device, * returns 1 if address is valid but device is not attached, * returns -1 if bad address or device is of an unsupported type. * Upon return sata_device argument is set. */ static int sata_validate_scsi_address(sata_hba_inst_t *sata_hba_inst, struct scsi_address *ap, sata_device_t *sata_device) { int cport, pmport, qual, rval; rval = -1; /* Invalid address */ if (ap->a_lun != 0) goto out; qual = SCSI_TO_SATA_ADDR_QUAL(ap->a_target); cport = SCSI_TO_SATA_CPORT(ap->a_target); pmport = SCSI_TO_SATA_PMPORT(ap->a_target); if (qual != SATA_ADDR_DCPORT && qual != SATA_ADDR_DPMPORT) goto out; if (sata_validate_sata_address(sata_hba_inst, cport, pmport, qual) == 0) { sata_cport_info_t *cportinfo; sata_pmult_info_t *pmultinfo; sata_drive_info_t *sdinfo = NULL; rval = 1; /* Valid sata address */ cportinfo = SATA_CPORT_INFO(sata_hba_inst, cport); if (qual == SATA_ADDR_DCPORT) { if (cportinfo == NULL || cportinfo->cport_dev_type == SATA_DTYPE_NONE) goto out; if (cportinfo->cport_dev_type == SATA_DTYPE_PMULT || (cportinfo->cport_dev_type & SATA_VALID_DEV_TYPE) == 0) { rval = -1; goto out; } sdinfo = SATA_CPORTINFO_DRV_INFO(cportinfo); } else if (qual == SATA_ADDR_DPMPORT) { pmultinfo = SATA_CPORTINFO_PMULT_INFO(cportinfo); if (pmultinfo == NULL) { rval = -1; goto out; } if (SATA_PMPORT_INFO(sata_hba_inst, cport, pmport) == NULL || SATA_PMPORT_DEV_TYPE(sata_hba_inst, cport, pmport) == SATA_DTYPE_NONE) goto out; sdinfo = SATA_PMPORT_DRV_INFO(sata_hba_inst, cport, pmport); } else { rval = -1; goto out; } if ((sdinfo == NULL) || (sdinfo->satadrv_type & SATA_VALID_DEV_TYPE) == 0) goto out; sata_device->satadev_type = sdinfo->satadrv_type; sata_device->satadev_addr.qual = qual; sata_device->satadev_addr.cport = cport; sata_device->satadev_addr.pmport = pmport; sata_device->satadev_rev = SATA_DEVICE_REV_1; return (0); } out: if (rval == 1) { SATADBG2(SATA_DBG_SCSI_IF, sata_hba_inst, "sata_validate_scsi_address: no valid target %x lun %x", ap->a_target, ap->a_lun); } return (rval); } /* * Find dip corresponding to passed device number * * Returns NULL if invalid device number is passed or device cannot be found, * Returns dip is device is found. */ static dev_info_t * sata_devt_to_devinfo(dev_t dev) { dev_info_t *dip; #ifndef __lock_lint struct devnames *dnp; major_t major = getmajor(dev); int instance = SATA_MINOR2INSTANCE(getminor(dev)); if (major >= devcnt) return (NULL); dnp = &devnamesp[major]; LOCK_DEV_OPS(&(dnp->dn_lock)); dip = dnp->dn_head; while (dip && (ddi_get_instance(dip) != instance)) { dip = ddi_get_next(dip); } UNLOCK_DEV_OPS(&(dnp->dn_lock)); #endif return (dip); } /* * Probe device. * This function issues Identify Device command and initialize local * sata_drive_info structure if the device can be identified. * The device type is determined by examining Identify Device * command response. * If the sata_hba_inst has linked drive info structure for this * device address, the Identify Device data is stored into sata_drive_info * structure linked to the port info structure. * * sata_device has to refer to the valid sata port(s) for HBA described * by sata_hba_inst structure. * * Returns: SATA_SUCCESS if device type was successfully probed and port-linked * drive info structure was updated; * SATA_FAILURE if there is no device, or device was not probed * successully. * If a device cannot be identified, sata_device's dev_state and dev_type * fields are set to unknown. * */ static int sata_probe_device(sata_hba_inst_t *sata_hba_inst, sata_device_t *sata_device) { sata_drive_info_t *sdinfo; sata_drive_info_t new_sdinfo; /* local drive info struct */ int retry_cnt; ASSERT((SATA_CPORT_STATE(sata_hba_inst, sata_device->satadev_addr.cport) & (SATA_STATE_PROBED | SATA_STATE_READY)) != 0); sata_device->satadev_type = SATA_DTYPE_NONE; mutex_enter(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device->satadev_addr.cport))); /* Get pointer to port-linked sata device info structure */ sdinfo = sata_get_device_info(sata_hba_inst, sata_device); if (sdinfo != NULL) { sdinfo->satadrv_state &= ~(SATA_STATE_PROBED | SATA_STATE_READY); sdinfo->satadrv_state |= SATA_STATE_PROBING; } else { /* No device to probe */ mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device->satadev_addr.cport))); sata_device->satadev_type = SATA_DTYPE_NONE; sata_device->satadev_state = SATA_STATE_UNKNOWN; return (SATA_FAILURE); } /* * Need to issue both types of identify device command and * determine device type by examining retreived data/status. * First, ATA Identify Device. */ bzero(&new_sdinfo, sizeof (sata_drive_info_t)); new_sdinfo.satadrv_addr = sata_device->satadev_addr; mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device->satadev_addr.cport))); for (retry_cnt = 0; retry_cnt <= SATA_DEVICE_IDENTIFY_RETRY; retry_cnt++) { new_sdinfo.satadrv_type = SATA_DTYPE_ATADISK; if (sata_identify_device(sata_hba_inst, &new_sdinfo) == 0) { /* Got something responding to ATA Identify Device */ if (sata_set_udma_mode(sata_hba_inst, &new_sdinfo) != SATA_SUCCESS) { /* Try one more time */ if (sata_set_udma_mode(sata_hba_inst, &new_sdinfo) != SATA_SUCCESS) goto failure; } sata_device->satadev_type = new_sdinfo.satadrv_type; break; } if (SATA_FEATURES(sata_hba_inst) & SATA_CTLF_ATAPI) { /* * HBA supports ATAPI - try to issue Identify Packet * Device command. */ new_sdinfo.satadrv_type = SATA_DTYPE_ATAPICD; if (sata_identify_device(sata_hba_inst, &new_sdinfo) == 0) { /* * Got something responding to Identify Packet * Device cmd. */ /* Set UDMA mode here as well ? - phase 2 */ sata_device->satadev_type = new_sdinfo.satadrv_type; break; } } } if (retry_cnt <= SATA_DEVICE_IDENTIFY_RETRY) { /* save device info, if possible */ mutex_enter(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device->satadev_addr.cport))); sdinfo = sata_get_device_info(sata_hba_inst, sata_device); if (sdinfo == NULL) { mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device->satadev_addr.cport))); return (SATA_FAILURE); } /* * Copy drive info into the port-linked drive info structure. */ *sdinfo = new_sdinfo; sdinfo->satadrv_state &= ~SATA_STATE_PROBING; sdinfo->satadrv_state |= SATA_STATE_PROBED; if (sata_device->satadev_addr.qual == SATA_ADDR_DCPORT) SATA_CPORT_DEV_TYPE(sata_hba_inst, sata_device->satadev_addr.cport) = sdinfo->satadrv_type; else /* SATA_ADDR_DPMPORT */ SATA_PMPORT_DEV_TYPE(sata_hba_inst, sata_device->satadev_addr.cport, sata_device->satadev_addr.pmport) = sdinfo->satadrv_type; mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device->satadev_addr.cport))); return (SATA_SUCCESS); } failure: /* * Looks like we cannot determine the device type. */ mutex_enter(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device->satadev_addr.cport))); sdinfo = sata_get_device_info(sata_hba_inst, sata_device); if (sdinfo != NULL) { sata_device->satadev_type = SATA_DTYPE_UNKNOWN; sdinfo->satadrv_type = SATA_DTYPE_UNKNOWN; sdinfo->satadrv_state &= ~SATA_STATE_PROBING; sdinfo->satadrv_state = SATA_STATE_PROBED; if (sata_device->satadev_addr.qual == SATA_ADDR_DCPORT) SATA_CPORT_DEV_TYPE(sata_hba_inst, sata_device->satadev_addr.cport) = SATA_DTYPE_UNKNOWN; else { /* SATA_ADDR_DPMPORT */ if ((SATA_PMULT_INFO(sata_hba_inst, sata_device->satadev_addr.cport) != NULL) && (SATA_PMPORT_INFO(sata_hba_inst, sata_device->satadev_addr.cport, sata_device->satadev_addr.pmport) != NULL)) SATA_PMPORT_DEV_TYPE(sata_hba_inst, sata_device->satadev_addr.cport, sata_device->satadev_addr.pmport) = SATA_DTYPE_UNKNOWN; } } mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, sata_device->satadev_addr.cport))); return (SATA_FAILURE); } /* * Get pointer to sata_drive_info structure. * * The sata_device has to contain address (cport, pmport and qualifier) for * specified sata_scsi structure. * * Returns NULL if device address is not valid for this HBA configuration. * Otherwise, returns a pointer to sata_drive_info structure. * * This function should be called with a port mutex held. */ static sata_drive_info_t * sata_get_device_info(sata_hba_inst_t *sata_hba_inst, sata_device_t *sata_device) { uint8_t cport = sata_device->satadev_addr.cport; uint8_t pmport = sata_device->satadev_addr.pmport; uint8_t qual = sata_device->satadev_addr.qual; if (cport >= SATA_NUM_CPORTS(sata_hba_inst)) return (NULL); if (!(SATA_CPORT_STATE(sata_hba_inst, cport) & (SATA_STATE_PROBED | SATA_STATE_READY))) /* Port not probed yet */ return (NULL); if (SATA_CPORT_DEV_TYPE(sata_hba_inst, cport) == SATA_DTYPE_NONE) return (NULL); if (qual == SATA_ADDR_DCPORT) { /* Request for a device on a controller port */ if (SATA_CPORT_DEV_TYPE(sata_hba_inst, cport) == SATA_DTYPE_PMULT) /* Port multiplier attached */ return (NULL); return (SATA_CPORT_DRV_INFO(sata_hba_inst, cport)); } if (qual == SATA_ADDR_DPMPORT) { if (SATA_CPORT_DEV_TYPE(sata_hba_inst, cport) != SATA_DTYPE_PMULT) return (NULL); if (pmport > SATA_NUM_PMPORTS(sata_hba_inst, cport)) return (NULL); return (SATA_PMPORT_DRV_INFO(sata_hba_inst, cport, pmport)); } /* we should not get here */ return (NULL); } /* * sata_identify_device. * Send Identify Device command to SATA HBA driver. * If command executes successfully, update sata_drive_info structure pointed * to by sdinfo argument, including Identify Device data. * If command fails, invalidate data in sata_drive_info. * * Cannot be called from interrupt level. * * Returns 0 if device was identified as supported device, -1 otherwise. */ static int sata_identify_device(sata_hba_inst_t *sata_hba_inst, sata_drive_info_t *sdinfo) { uint16_t cfg_word; int i; /* fetch device identify data */ if (sata_fetch_device_identify_data(sata_hba_inst, sdinfo) != 0) goto fail_unknown; cfg_word = sdinfo->satadrv_id.ai_config; if (sdinfo->satadrv_type == SATA_DTYPE_ATADISK && (cfg_word & SATA_ATA_TYPE_MASK) != SATA_ATA_TYPE) { /* Change device type to reflect Identify Device data */ if (((cfg_word & SATA_ATAPI_TYPE_MASK) == SATA_ATAPI_TYPE) && ((cfg_word & SATA_ATAPI_ID_DEV_TYPE) == SATA_ATAPI_CDROM_DEV)) { sdinfo->satadrv_type = SATA_DTYPE_ATAPICD; } else { sdinfo->satadrv_type = SATA_DTYPE_UNKNOWN; } } else if (sdinfo->satadrv_type == SATA_DTYPE_ATAPICD && (((cfg_word & SATA_ATAPI_TYPE_MASK) != SATA_ATAPI_TYPE) || ((cfg_word & SATA_ATAPI_ID_DEV_TYPE) != SATA_ATAPI_CDROM_DEV))) { /* Change device type to reflect Identify Device data ! */ if ((sdinfo->satadrv_id.ai_config & SATA_ATA_TYPE_MASK) == SATA_ATA_TYPE) { sdinfo->satadrv_type = SATA_DTYPE_ATADISK; } else { sdinfo->satadrv_type = SATA_DTYPE_UNKNOWN; } } if (sdinfo->satadrv_type == SATA_DTYPE_ATADISK) { if (sdinfo->satadrv_capacity == 0) { /* Non-LBA disk. Too bad... */ sata_log(sata_hba_inst, CE_WARN, "SATA disk device at port %d does not support LBA", sdinfo->satadrv_addr.cport); goto fail_unknown; } } /* Check for Ultra DMA modes 6 through 0 being supported */ for (i = 6; i >= 0; --i) { if (sdinfo->satadrv_id.ai_ultradma & (1 << i)) break; } /* * At least UDMA 4 mode has to be supported. If mode 4 or * higher are not supported by the device, fail this * device. */ if (i < 4) { /* No required Ultra DMA mode supported */ sata_log(sata_hba_inst, CE_WARN, "SATA disk device at port %d does not support UDMA " "mode 4 or higher", sdinfo->satadrv_addr.cport); SATA_LOG_D((sata_hba_inst, CE_WARN, "mode 4 or higher required, %d supported", i)); goto fail_unknown; } return (0); fail_unknown: /* Invalidate sata_drive_info ? */ sdinfo->satadrv_type = SATA_DTYPE_UNKNOWN; sdinfo->satadrv_state = SATA_STATE_UNKNOWN; return (-1); } /* * Log/display device information */ static void sata_show_drive_info(sata_hba_inst_t *sata_hba_inst, sata_drive_info_t *sdinfo) { int valid_version; char msg_buf[MAXPATHLEN]; /* Show HBA path */ (void) ddi_pathname(SATA_DIP(sata_hba_inst), msg_buf); cmn_err(CE_CONT, "?%s :\n", msg_buf); if (sdinfo->satadrv_type == SATA_DTYPE_UNKNOWN) { (void) sprintf(msg_buf, "Unsupported SATA device type (cfg 0x%x) at ", sdinfo->satadrv_id.ai_config); } else { (void) sprintf(msg_buf, "SATA %s device at", sdinfo->satadrv_type == SATA_DTYPE_ATADISK ? "disk":"CD/DVD (ATAPI)"); } if (sdinfo->satadrv_addr.qual == SATA_ADDR_DCPORT) cmn_err(CE_CONT, "?\t%s port %d\n", msg_buf, sdinfo->satadrv_addr.cport); else cmn_err(CE_CONT, "?\t%s port %d pmport %d\n", msg_buf, sdinfo->satadrv_addr.cport, sdinfo->satadrv_addr.pmport); bcopy(&sdinfo->satadrv_id.ai_model, msg_buf, sizeof (sdinfo->satadrv_id.ai_model)); swab(msg_buf, msg_buf, sizeof (sdinfo->satadrv_id.ai_model)); msg_buf[sizeof (sdinfo->satadrv_id.ai_model)] = '\0'; cmn_err(CE_CONT, "?\tmodel %s\n", msg_buf); bcopy(&sdinfo->satadrv_id.ai_fw, msg_buf, sizeof (sdinfo->satadrv_id.ai_fw)); swab(msg_buf, msg_buf, sizeof (sdinfo->satadrv_id.ai_fw)); msg_buf[sizeof (sdinfo->satadrv_id.ai_fw)] = '\0'; cmn_err(CE_CONT, "?\tfirmware %s\n", msg_buf); bcopy(&sdinfo->satadrv_id.ai_drvser, msg_buf, sizeof (sdinfo->satadrv_id.ai_drvser)); swab(msg_buf, msg_buf, sizeof (sdinfo->satadrv_id.ai_drvser)); msg_buf[sizeof (sdinfo->satadrv_id.ai_drvser)] = '\0'; cmn_err(CE_CONT, "?\tserial number %s\n", msg_buf); #ifdef SATA_DEBUG if (sdinfo->satadrv_id.ai_majorversion != 0 && sdinfo->satadrv_id.ai_majorversion != 0xffff) { int i; for (i = 14; i >= 2; i--) { if (sdinfo->satadrv_id.ai_majorversion & (1 << i)) { valid_version = i; break; } } cmn_err(CE_CONT, "?\tATA/ATAPI-%d supported, majver 0x%x minver 0x%x\n", valid_version, sdinfo->satadrv_id.ai_majorversion, sdinfo->satadrv_id.ai_minorversion); } #endif /* Log some info */ cmn_err(CE_CONT, "?\tsupported features:\n"); msg_buf[0] = '\0'; if (sdinfo->satadrv_features_support & SATA_DEV_F_LBA48) (void) strlcat(msg_buf, "48-bit LBA", MAXPATHLEN); else if (sdinfo->satadrv_features_support & SATA_DEV_F_LBA28) (void) strlcat(msg_buf, "28-bit LBA", MAXPATHLEN); if (sdinfo->satadrv_features_support & SATA_DEV_F_DMA) (void) strlcat(msg_buf, ", DMA", MAXPATHLEN); if (sdinfo->satadrv_features_support & SATA_DEV_F_NCQ) (void) strlcat(msg_buf, ", Native Command Queueing", MAXPATHLEN); else if (sdinfo->satadrv_id.ai_cmdset83 & SATA_RW_DMA_QUEUED_CMD) (void) strlcat(msg_buf, ", Queuing", MAXPATHLEN); if ((sdinfo->satadrv_id.ai_cmdset82 & SATA_SMART_SUPPORTED) && (sdinfo->satadrv_id.ai_features85 & SATA_SMART_ENABLED)) (void) strlcat(msg_buf, ", SMART", MAXPATHLEN); if ((sdinfo->satadrv_id.ai_cmdset84 & SATA_SMART_SELF_TEST_SUPPORTED) && (sdinfo->satadrv_id.ai_features87 & SATA_SMART_SELF_TEST_SUPPORTED)) (void) strlcat(msg_buf, ", SMART self-test", MAXPATHLEN); cmn_err(CE_CONT, "?\t %s\n", msg_buf); if (sdinfo->satadrv_features_support & SATA_DEV_F_SATA2) cmn_err(CE_CONT, "?\tSATA1 & SATA2 compatible\n"); else if (sdinfo->satadrv_features_support & SATA_DEV_F_SATA1) cmn_err(CE_CONT, "?\tSATA1 compatible\n"); #ifdef __i386 (void) sprintf(msg_buf, "\tcapacity = %llu sectors\n", sdinfo->satadrv_capacity); #else (void) sprintf(msg_buf, "\tcapacity = %lu sectors\n", sdinfo->satadrv_capacity); #endif cmn_err(CE_CONT, "?%s", msg_buf); } /* * sata_save_drive_settings extracts current setting of the device and stores * it for future reference, in case the device setup would need to be restored * after the device reset. * * At the moment only read ahead and write cache settings are saved, if the * device supports these features at all. */ static void sata_save_drive_settings(sata_drive_info_t *sdinfo) { if (!(sdinfo->satadrv_id.ai_cmdset82 & SATA_LOOK_AHEAD) && !(sdinfo->satadrv_id.ai_cmdset82 & SATA_WRITE_CACHE)) { /* None of the features is supported - do nothing */ return; } /* Current setting of Read Ahead (and Read Cache) */ if (sdinfo->satadrv_id.ai_features85 & SATA_LOOK_AHEAD) sdinfo->satadrv_settings |= SATA_DEV_READ_AHEAD; else sdinfo->satadrv_settings &= ~SATA_DEV_READ_AHEAD; /* Current setting of Write Cache */ if (sdinfo->satadrv_id.ai_features85 & SATA_WRITE_CACHE) sdinfo->satadrv_settings |= SATA_DEV_WRITE_CACHE; else sdinfo->satadrv_settings &= ~SATA_DEV_WRITE_CACHE; } /* * sata_check_capacity function determines a disk capacity * and addressing mode (LBA28/LBA48) by examining a disk identify device data. * * NOTE: CHS mode is not supported! If a device does not support LBA, * this function is not called. * * Returns device capacity in number of blocks, i.e. largest addressable LBA+1 */ static uint64_t sata_check_capacity(sata_drive_info_t *sdinfo) { uint64_t capacity = 0; int i; if (sdinfo->satadrv_type != SATA_DTYPE_ATADISK || !sdinfo->satadrv_id.ai_cap & SATA_LBA_SUPPORT) /* Capacity valid only for LBA-addressable disk devices */ return (0); if ((sdinfo->satadrv_id.ai_validinfo & SATA_VALIDINFO_88) && (sdinfo->satadrv_id.ai_cmdset83 & SATA_EXT48) && (sdinfo->satadrv_id.ai_features86 & SATA_EXT48)) { /* LBA48 mode supported and enabled */ sdinfo->satadrv_features_support |= SATA_DEV_F_LBA48 | SATA_DEV_F_LBA28; for (i = 3; i >= 0; --i) { capacity <<= 16; capacity += sdinfo->satadrv_id.ai_addrsecxt[i]; } } else { capacity = sdinfo->satadrv_id.ai_addrsec[1]; capacity <<= 16; capacity += sdinfo->satadrv_id.ai_addrsec[0]; if (capacity >= 0x1000000) /* LBA28 mode */ sdinfo->satadrv_features_support |= SATA_DEV_F_LBA28; } return (capacity); } /* * Allocate consistent buffer for DMA transfer * * Cannot be called from interrupt level or with mutex held - it may sleep. * * Returns pointer to allocated buffer structure, or NULL if allocation failed. */ static struct buf * sata_alloc_local_buffer(sata_pkt_txlate_t *spx, int len) { struct scsi_address ap; struct buf *bp; ddi_dma_attr_t cur_dma_attr; ASSERT(spx->txlt_sata_pkt != NULL); ap.a_hba_tran = spx->txlt_sata_hba_inst->satahba_scsi_tran; ap.a_target = SATA_TO_SCSI_TARGET( spx->txlt_sata_pkt->satapkt_device.satadev_addr.cport, spx->txlt_sata_pkt->satapkt_device.satadev_addr.pmport, spx->txlt_sata_pkt->satapkt_device.satadev_addr.qual); ap.a_lun = 0; bp = scsi_alloc_consistent_buf(&ap, NULL, len, B_READ, SLEEP_FUNC, NULL); if (bp != NULL) { /* Allocate DMA resources for this buffer */ spx->txlt_sata_pkt->satapkt_cmd.satacmd_bp = bp; /* * We use a local version of the dma_attr, to account * for a device addressing limitations. * sata_adjust_dma_attr() will handle sdinfo == NULL which * will cause dma attributes to be adjusted to a lowest * acceptable level. */ sata_adjust_dma_attr(NULL, SATA_DMA_ATTR(spx->txlt_sata_hba_inst), &cur_dma_attr); if (sata_dma_buf_setup(spx, PKT_CONSISTENT, SLEEP_FUNC, NULL, &cur_dma_attr) != DDI_SUCCESS) { scsi_free_consistent_buf(bp); spx->txlt_sata_pkt->satapkt_cmd.satacmd_bp = NULL; bp = NULL; } } return (bp); } /* * Release local buffer (consistent buffer for DMA transfer) allocated * via sata_alloc_local_buffer(). */ static void sata_free_local_buffer(sata_pkt_txlate_t *spx) { ASSERT(spx->txlt_sata_pkt != NULL); ASSERT(spx->txlt_dma_cookie_list != NULL); ASSERT(spx->txlt_dma_cookie_list_len != 0); ASSERT(spx->txlt_buf_dma_handle != NULL); ASSERT(spx->txlt_sata_pkt->satapkt_cmd.satacmd_bp != NULL); spx->txlt_sata_pkt->satapkt_cmd.satacmd_num_dma_cookies = 0; spx->txlt_sata_pkt->satapkt_cmd.satacmd_dma_cookie_list = NULL; /* Free DMA resources */ (void) ddi_dma_unbind_handle(spx->txlt_buf_dma_handle); ddi_dma_free_handle(&spx->txlt_buf_dma_handle); spx->txlt_buf_dma_handle = 0; kmem_free(spx->txlt_dma_cookie_list, spx->txlt_dma_cookie_list_len * sizeof (ddi_dma_cookie_t)); spx->txlt_dma_cookie_list = NULL; spx->txlt_dma_cookie_list_len = 0; /* Free buffer */ scsi_free_consistent_buf(spx->txlt_sata_pkt->satapkt_cmd.satacmd_bp); } /* * Allocate sata_pkt * Pkt structure version and embedded strcutures version are initialized. * sata_pkt and sata_pkt_txlate structures are cross-linked. * * Since this may be called in interrupt context by sata_scsi_init_pkt, * callback argument determines if it can sleep or not. * Hence, it should not be called from interrupt context. * * If successful, non-NULL pointer to a sata pkt is returned. * Upon failure, NULL pointer is returned. */ static sata_pkt_t * sata_pkt_alloc(sata_pkt_txlate_t *spx, int (*callback)(caddr_t)) { sata_pkt_t *spkt; int kmsflag; kmsflag = (callback == SLEEP_FUNC) ? KM_SLEEP : KM_NOSLEEP; spkt = kmem_zalloc(sizeof (sata_pkt_t), kmsflag); if (spkt == NULL) { SATA_LOG_D((spx->txlt_sata_hba_inst, CE_WARN, "sata_pkt_alloc: failed")); return (NULL); } spkt->satapkt_rev = SATA_PKT_REV; spkt->satapkt_cmd.satacmd_rev = SATA_CMD_REV; spkt->satapkt_device.satadev_rev = SATA_DEVICE_REV; spkt->satapkt_framework_private = spx; spx->txlt_sata_pkt = spkt; return (spkt); } /* * Free sata pkt allocated via sata_pkt_alloc() */ static void sata_pkt_free(sata_pkt_txlate_t *spx) { ASSERT(spx->txlt_sata_pkt != NULL); ASSERT(spx->txlt_sata_pkt->satapkt_cmd.satacmd_bp == NULL); kmem_free(spx->txlt_sata_pkt, sizeof (sata_pkt_t)); spx->txlt_sata_pkt = NULL; } /* * Adjust DMA attributes. * SCSI cmds block count is up to 24 bits, SATA cmd block count vary * from 8 bits to 16 bits, depending on a command being used. * Limiting max block count arbitrarily to 256 for all read/write * commands may affects performance, so check both the device and * controller capability before adjusting dma attributes. * For ATAPI CD/DVD dma granularity has to be adjusted as well, * because these devices support block size of 2k rather * then 512 bytes. */ void sata_adjust_dma_attr(sata_drive_info_t *sdinfo, ddi_dma_attr_t *dma_attr, ddi_dma_attr_t *adj_dma_attr) { uint32_t count_max; /* Copy original attributes */ *adj_dma_attr = *dma_attr; /* * Things to consider: device addressing capability, * "excessive" controller DMA capabilities. * If a device is being probed/initialized, there are * no device info - use default limits then. */ if (sdinfo == NULL) { count_max = dma_attr->dma_attr_granular * 0x100; if (dma_attr->dma_attr_count_max > count_max) adj_dma_attr->dma_attr_count_max = count_max; if (dma_attr->dma_attr_maxxfer > count_max) adj_dma_attr->dma_attr_maxxfer = count_max; return; } if (sdinfo->satadrv_type == SATA_DTYPE_ATAPICD) { /* arbitrarily modify controller dma granularity */ adj_dma_attr->dma_attr_granular = SATA_ATAPI_SECTOR_SIZE; } if (sdinfo->satadrv_features_support & (SATA_DEV_F_LBA48)) { /* * 16-bit sector count may be used - we rely on * the assumption that only read and write cmds * will request more than 256 sectors worth of data */ count_max = adj_dma_attr->dma_attr_granular * 0x10000; } else { /* * 8-bit sector count will be used - default limits * for dma attributes */ count_max = adj_dma_attr->dma_attr_granular * 0x100; } /* * Adjust controler dma attributes, if necessary */ if (dma_attr->dma_attr_count_max > count_max) adj_dma_attr->dma_attr_count_max = count_max; if (dma_attr->dma_attr_maxxfer > count_max) adj_dma_attr->dma_attr_maxxfer = count_max; } /* * Allocate DMA resources for the buffer * This function handles initial DMA resource allocation as well as * DMA window shift and may be called repeatedly for the same DMA window * until all DMA cookies in the DMA window are processed. * * Returns DDI_SUCCESS upon successful operation, * returns failure code returned by failing commands or DDI_FAILURE when * internal cleanup failed. */ static int sata_dma_buf_setup(sata_pkt_txlate_t *spx, int flags, int (*callback)(caddr_t), caddr_t arg, ddi_dma_attr_t *cur_dma_attr) { int rval; ddi_dma_cookie_t cookie; off_t offset; size_t size; int max_sg_len, req_sg_len, i; uint_t dma_flags; struct buf *bp; uint64_t max_txfer_len; uint64_t cur_txfer_len; ASSERT(spx->txlt_sata_pkt != NULL); bp = spx->txlt_sata_pkt->satapkt_cmd.satacmd_bp; ASSERT(bp != NULL); if (spx->txlt_buf_dma_handle == NULL) { /* * No DMA resources allocated so far - this is a first call * for this sata pkt. */ rval = ddi_dma_alloc_handle(SATA_DIP(spx->txlt_sata_hba_inst), cur_dma_attr, callback, arg, &spx->txlt_buf_dma_handle); if (rval != DDI_SUCCESS) { SATA_LOG_D((spx->txlt_sata_hba_inst, CE_WARN, "sata_dma_buf_setup: no buf DMA resources %x", rval)); return (rval); } if (bp->b_flags & B_READ) dma_flags = DDI_DMA_READ; else dma_flags = DDI_DMA_WRITE; if (flags & PKT_CONSISTENT) dma_flags |= DDI_DMA_CONSISTENT; if (flags & PKT_DMA_PARTIAL) dma_flags |= DDI_DMA_PARTIAL; rval = ddi_dma_buf_bind_handle(spx->txlt_buf_dma_handle, bp, dma_flags, callback, arg, &cookie, &spx->txlt_curwin_num_dma_cookies); switch (rval) { case DDI_DMA_PARTIAL_MAP: SATADBG1(SATA_DBG_DMA_SETUP, spx->txlt_sata_hba_inst, "sata_dma_buf_setup: DMA Partial Map\n", NULL); /* * Partial DMA mapping. * Retrieve number of DMA windows for this request. */ if (ddi_dma_numwin(spx->txlt_buf_dma_handle, &spx->txlt_num_dma_win) != DDI_SUCCESS) { (void) ddi_dma_unbind_handle( spx->txlt_buf_dma_handle); (void) ddi_dma_free_handle( &spx->txlt_buf_dma_handle); spx->txlt_buf_dma_handle = NULL; SATA_LOG_D((spx->txlt_sata_hba_inst, CE_WARN, "sata_dma_buf_setup: numwin failed\n")); return (DDI_FAILURE); } spx->txlt_cur_dma_win = 0; break; case DDI_DMA_MAPPED: /* DMA fully mapped */ spx->txlt_num_dma_win = 1; spx->txlt_cur_dma_win = 0; break; default: /* DMA mapping failed */ (void) ddi_dma_free_handle(&spx->txlt_buf_dma_handle); spx->txlt_buf_dma_handle = NULL; SATA_LOG_D((spx->txlt_sata_hba_inst, CE_WARN, "sata_dma_buf_setup: buf dma handle binding " "failed %x\n", rval)); return (rval); } spx->txlt_curwin_processed_dma_cookies = 0; spx->txlt_dma_cookie_list = NULL; } else { /* * DMA setup is reused. Check if we need to process more * cookies in current window, or to get next window, if any. */ ASSERT(spx->txlt_curwin_processed_dma_cookies <= spx->txlt_curwin_num_dma_cookies); if (spx->txlt_curwin_processed_dma_cookies == spx->txlt_curwin_num_dma_cookies) { /* * All cookies from current DMA window were processed. * Get next DMA window. */ spx->txlt_cur_dma_win++; if (spx->txlt_cur_dma_win < spx->txlt_num_dma_win) { (void) ddi_dma_getwin(spx->txlt_buf_dma_handle, spx->txlt_cur_dma_win, &offset, &size, &cookie, &spx->txlt_curwin_num_dma_cookies); spx->txlt_curwin_processed_dma_cookies = 0; } else { /* No more windows! End of request! */ /* What to do? - panic for now */ ASSERT(spx->txlt_cur_dma_win >= spx->txlt_num_dma_win); spx->txlt_curwin_num_dma_cookies = 0; spx->txlt_curwin_processed_dma_cookies = 0; spx->txlt_sata_pkt-> satapkt_cmd.satacmd_num_dma_cookies = 0; return (DDI_SUCCESS); } } } /* There better be at least one DMA cookie */ ASSERT((spx->txlt_curwin_num_dma_cookies - spx->txlt_curwin_processed_dma_cookies) > 0); if (spx->txlt_curwin_processed_dma_cookies == 0) { /* * Processing a new DMA window - set-up dma cookies list. * We may reuse previously allocated cookie array if it is * possible. */ if (spx->txlt_dma_cookie_list != NULL && spx->txlt_dma_cookie_list_len < spx->txlt_curwin_num_dma_cookies) { /* * New DMA window contains more cookies than * the previous one. We need larger cookie list - free * the old one. */ (void) kmem_free(spx->txlt_dma_cookie_list, spx->txlt_dma_cookie_list_len * sizeof (ddi_dma_cookie_t)); spx->txlt_dma_cookie_list = NULL; spx->txlt_dma_cookie_list_len = 0; } if (spx->txlt_dma_cookie_list == NULL) { /* Allocate new dma cookie array */ spx->txlt_dma_cookie_list = kmem_zalloc( sizeof (ddi_dma_cookie_t) * spx->txlt_curwin_num_dma_cookies, KM_SLEEP); spx->txlt_dma_cookie_list_len = spx->txlt_curwin_num_dma_cookies; } /* * Copy all DMA cookies into local list, so we will know their * dma_size in advance of setting the sata_pkt. * One cookie was already fetched, so copy it. */ *(&spx->txlt_dma_cookie_list[0]) = cookie; for (i = 1; i < spx->txlt_curwin_num_dma_cookies; i++) { ddi_dma_nextcookie(spx->txlt_buf_dma_handle, &cookie); *(&spx->txlt_dma_cookie_list[i]) = cookie; } } else { SATADBG2(SATA_DBG_DMA_SETUP, spx->txlt_sata_hba_inst, "sata_dma_buf_setup: sliding within DMA window, " "cur cookie %d, total cookies %d\n", spx->txlt_curwin_processed_dma_cookies, spx->txlt_curwin_num_dma_cookies); } /* * Set-up sata_pkt cookie list. * No single cookie transfer size would exceed max transfer size of * an ATA command used for addressed device (tha adjustment of the dma * attributes took care of this). But there may be more * then one cookie, so the cmd cookie list has to be * constrained by both a maximum scatter gather list length and * a maximum transfer size restriction of an ATA command. */ max_sg_len = cur_dma_attr->dma_attr_sgllen; req_sg_len = MIN(max_sg_len, (spx->txlt_curwin_num_dma_cookies - spx->txlt_curwin_processed_dma_cookies)); ASSERT(req_sg_len > 0); max_txfer_len = MAX((cur_dma_attr->dma_attr_granular * 0x100), cur_dma_attr->dma_attr_maxxfer); /* One cookie should be always available */ spx->txlt_sata_pkt->satapkt_cmd.satacmd_dma_cookie_list = &spx->txlt_dma_cookie_list[spx->txlt_curwin_processed_dma_cookies]; spx->txlt_sata_pkt->satapkt_cmd.satacmd_num_dma_cookies = 1; cur_txfer_len = (uint64_t)spx->txlt_dma_cookie_list[ spx->txlt_curwin_processed_dma_cookies].dmac_size; spx->txlt_curwin_processed_dma_cookies++; ASSERT(cur_txfer_len <= max_txfer_len); /* Add more cookies to the scatter-gather list */ for (i = 1; i < req_sg_len; i++) { if (cur_txfer_len < max_txfer_len) { /* * Check if the next cookie could be used by * this sata_pkt. */ if ((cur_txfer_len + spx->txlt_dma_cookie_list[ spx->txlt_curwin_processed_dma_cookies]. dmac_size) <= max_txfer_len) { /* Yes, transfer lenght is within bounds */ spx->txlt_sata_pkt-> satapkt_cmd.satacmd_num_dma_cookies++; cur_txfer_len += spx->txlt_dma_cookie_list[ spx->txlt_curwin_processed_dma_cookies]. dmac_size; spx->txlt_curwin_processed_dma_cookies++; } else { /* No, transfer would exceed max lenght. */ SATADBG3(SATA_DBG_DMA_SETUP, spx->txlt_sata_hba_inst, "ncookies %d, size 0x%lx, " "max_size 0x%lx\n", spx->txlt_sata_pkt-> satapkt_cmd.satacmd_num_dma_cookies, cur_txfer_len, max_txfer_len); break; } } else { /* Cmd max transfer length reached */ SATADBG3(SATA_DBG_DMA_SETUP, spx->txlt_sata_hba_inst, "Max transfer length? " "ncookies %d, size 0x%lx, max_size 0x%lx\n", spx->txlt_sata_pkt-> satapkt_cmd.satacmd_num_dma_cookies, cur_txfer_len, max_txfer_len); break; } } ASSERT(cur_txfer_len != 0); spx->txlt_total_residue -= cur_txfer_len; return (DDI_SUCCESS); } /* * Fetch Device Identify data. * Send DEVICE IDENTIFY command to a device and get the device identify data. * The device_info structure has to be set to device type (for selecting proper * device identify command). * * Returns 0 if success, -1 otherwise. * * Cannot be called in an interrupt context. */ static int sata_fetch_device_identify_data(sata_hba_inst_t *sata_hba_inst, sata_drive_info_t *sdinfo) { struct buf *bp; sata_pkt_t *spkt; sata_cmd_t *scmd; sata_pkt_txlate_t *spx; int rval; spx = kmem_zalloc(sizeof (sata_pkt_txlate_t), KM_SLEEP); spx->txlt_sata_hba_inst = sata_hba_inst; spx->txlt_scsi_pkt = NULL; /* No scsi pkt involved */ spkt = sata_pkt_alloc(spx, SLEEP_FUNC); if (spkt == NULL) { kmem_free(spx, sizeof (sata_pkt_txlate_t)); return (-1); } /* address is needed now */ spkt->satapkt_device.satadev_addr = sdinfo->satadrv_addr; /* * Allocate buffer for Identify Data return data */ bp = sata_alloc_local_buffer(spx, sizeof (sata_id_t)); if (bp == NULL) { sata_pkt_free(spx); kmem_free(spx, sizeof (sata_pkt_txlate_t)); SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_fetch_device_identify_data: " "cannot allocate buffer for ID")); return (-1); } /* Fill sata_pkt */ sdinfo->satadrv_state = SATA_STATE_PROBING; spkt->satapkt_device.satadev_addr = sdinfo->satadrv_addr; spkt->satapkt_op_mode = SATA_OPMODE_SYNCH | SATA_OPMODE_INTERRUPTS; /* Synchronous mode, no callback */ spkt->satapkt_comp = NULL; /* Timeout 30s */ spkt->satapkt_time = sata_default_pkt_time; scmd = &spkt->satapkt_cmd; scmd->satacmd_bp = bp; scmd->satacmd_flags.sata_data_direction = SATA_DIR_READ; scmd->satacmd_flags.sata_ignore_dev_reset = B_TRUE; /* Build Identify Device cmd in the sata_pkt */ scmd->satacmd_addr_type = 0; /* N/A */ scmd->satacmd_sec_count_lsb = 0; /* N/A */ scmd->satacmd_lba_low_lsb = 0; /* N/A */ scmd->satacmd_lba_mid_lsb = 0; /* N/A */ scmd->satacmd_lba_high_lsb = 0; /* N/A */ scmd->satacmd_features_reg = 0; /* N/A */ scmd->satacmd_device_reg = 0; /* Always device 0 */ if (sdinfo->satadrv_type == SATA_DTYPE_ATAPICD) { /* Identify Packet Device cmd */ scmd->satacmd_cmd_reg = SATAC_ID_PACKET_DEVICE; } else { /* Identify Device cmd - mandatory for all other devices */ scmd->satacmd_cmd_reg = SATAC_ID_DEVICE; } /* Send pkt to SATA HBA driver */ if ((*SATA_START_FUNC(sata_hba_inst))(SATA_DIP(sata_hba_inst), spkt) != SATA_TRAN_ACCEPTED || spkt->satapkt_reason != SATA_PKT_COMPLETED) { /* * Woops, no Identify Data. * Invalidate sata_drive_info ? */ rval = -1; } else { /* Update sata_drive_info */ rval = ddi_dma_sync(spx->txlt_buf_dma_handle, 0, 0, DDI_DMA_SYNC_FORKERNEL); if (rval != DDI_SUCCESS) { SATA_LOG_D((spx->txlt_sata_hba_inst, CE_WARN, "sata_fetch_device_identify_data: " "sync pkt failed")); rval = -1; goto fail; } bcopy(bp->b_un.b_addr, &sdinfo->satadrv_id, sizeof (sata_id_t)); sdinfo->satadrv_features_support = 0; if (sdinfo->satadrv_type == SATA_DTYPE_ATADISK) { /* * Retrieve capacity (disks only) and addressing mode */ sdinfo->satadrv_capacity = sata_check_capacity(sdinfo); } else { /* * For ATAPI devices one has to issue Get Capacity cmd * (not needed at the moment) */ sdinfo->satadrv_capacity = 0; } /* Setup supported features flags */ if (sdinfo->satadrv_id.ai_cap & SATA_DMA_SUPPORT) sdinfo->satadrv_features_support |= SATA_DEV_F_DMA; /* Check for NCQ support */ if (sdinfo->satadrv_id.ai_satacap != 0 && sdinfo->satadrv_id.ai_satacap != 0xffff) { /* SATA compliance */ if (sdinfo->satadrv_id.ai_satacap & SATA_NCQ) sdinfo->satadrv_features_support |= SATA_DEV_F_NCQ; if (sdinfo->satadrv_id.ai_satacap & (SATA_1_SPEED | SATA_2_SPEED)) { if (sdinfo->satadrv_id.ai_satacap & SATA_2_SPEED) sdinfo->satadrv_features_support |= SATA_DEV_F_SATA2; if (sdinfo->satadrv_id.ai_satacap & SATA_1_SPEED) sdinfo->satadrv_features_support |= SATA_DEV_F_SATA1; } else { sdinfo->satadrv_features_support |= SATA_DEV_F_SATA1; } } sdinfo->satadrv_queue_depth = sdinfo->satadrv_id.ai_qdepth; if (sdinfo->satadrv_id.ai_cmdset83 & SATA_RW_DMA_QUEUED_CMD) if (sdinfo->satadrv_queue_depth == 0) sdinfo->satadrv_queue_depth = 1; rval = 0; } fail: /* Free allocated resources */ sata_free_local_buffer(spx); spx->txlt_sata_pkt->satapkt_cmd.satacmd_bp = NULL; sata_pkt_free(spx); kmem_free(spx, sizeof (sata_pkt_txlate_t)); return (rval); } /* * SATA spec requires that the device supports at least UDMA 4 mode and * UDMA mode is selected. * Some devices (bridged devices) may not come-up with default UDMA mode * set correctly, so this function is setting it. * * Returns SATA_SUCCESS if proper UDMA mode is selected. * Returns SATA_FAILURE if proper UDMA mode could not be selected. */ static int sata_set_udma_mode(sata_hba_inst_t *sata_hba_inst, sata_drive_info_t *sdinfo) { sata_pkt_t *spkt; sata_cmd_t *scmd; sata_pkt_txlate_t *spx; int result = SATA_SUCCESS; int i, mode; ASSERT(sdinfo != NULL); ASSERT(sata_hba_inst != NULL); /* Find highest Ultra DMA mode supported */ for (mode = 6; mode >= 0; --mode) { if (sdinfo->satadrv_id.ai_ultradma & (1 << mode)) break; } if (mode < 4) return (SATA_FAILURE); /* Find UDMA mode currently selected */ for (i = 6; i >= 0; --i) { if (sdinfo->satadrv_id.ai_ultradma & (1 << (i + 8))) break; } if (i < mode) { /* Set UDMA mode via SET FEATURES COMMAND */ /* Prepare packet for SET FEATURES COMMAND */ spx = kmem_zalloc(sizeof (sata_pkt_txlate_t), KM_SLEEP); spx->txlt_sata_hba_inst = sata_hba_inst; spx->txlt_scsi_pkt = NULL; /* No scsi pkt involved */ spkt = sata_pkt_alloc(spx, SLEEP_FUNC); if (spkt == NULL) { result = SATA_FAILURE; goto failure; } /* Fill sata_pkt */ spkt->satapkt_device.satadev_addr = sdinfo->satadrv_addr; /* Timeout 30s */ spkt->satapkt_time = sata_default_pkt_time; /* Synchronous mode, no callback, interrupts */ spkt->satapkt_op_mode = SATA_OPMODE_SYNCH | SATA_OPMODE_INTERRUPTS; spkt->satapkt_comp = NULL; scmd = &spkt->satapkt_cmd; scmd->satacmd_flags.sata_data_direction = SATA_DIR_NODATA_XFER; scmd->satacmd_flags.sata_ignore_dev_reset = B_TRUE; scmd->satacmd_addr_type = 0; scmd->satacmd_device_reg = 0; scmd->satacmd_status_reg = 0; scmd->satacmd_error_reg = 0; scmd->satacmd_cmd_reg = SATAC_SET_FEATURES; scmd->satacmd_features_reg = SATAC_SF_TRANSFER_MODE; scmd->satacmd_sec_count_lsb = SATAC_TRANSFER_MODE_ULTRA_DMA | mode; /* Transfer command to HBA */ if ((*SATA_START_FUNC(sata_hba_inst))(SATA_DIP(sata_hba_inst), spkt) != SATA_TRAN_ACCEPTED || spkt->satapkt_reason != SATA_PKT_COMPLETED) { /* Pkt execution failed */ result = SATA_FAILURE; } failure: if (result == SATA_FAILURE) SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_set_udma_mode: could not set UDMA " "mode %", mode)); /* Free allocated resources */ if (spkt != NULL) sata_pkt_free(spx); (void) kmem_free(spx, sizeof (sata_pkt_txlate_t)); } return (result); } /* * Update port SCR block */ static void sata_update_port_scr(sata_port_scr_t *port_scr, sata_device_t *device) { port_scr->sstatus = device->satadev_scr.sstatus; port_scr->serror = device->satadev_scr.serror; port_scr->scontrol = device->satadev_scr.scontrol; port_scr->sactive = device->satadev_scr.sactive; port_scr->snotific = device->satadev_scr.snotific; } /* * Update state and copy port ss* values from passed sata_device structure. * sata_address is validated - if not valid, nothing is changed in sata_scsi * configuration struct. * * SATA_PSTATE_SHUTDOWN in port state is not reset to 0 by this function * regardless of the state in device argument. * * Port mutex should be held while calling this function. */ static void sata_update_port_info(sata_hba_inst_t *sata_hba_inst, sata_device_t *sata_device) { ASSERT(mutex_owned(&SATA_CPORT_MUTEX(sata_hba_inst, sata_device->satadev_addr.cport))); if (sata_device->satadev_addr.qual == SATA_ADDR_CPORT || sata_device->satadev_addr.qual == SATA_ADDR_DCPORT) { sata_cport_info_t *cportinfo; if (SATA_NUM_CPORTS(sata_hba_inst) <= sata_device->satadev_addr.cport) return; cportinfo = SATA_CPORT_INFO(sata_hba_inst, sata_device->satadev_addr.cport); sata_update_port_scr(&cportinfo->cport_scr, sata_device); /* Preserve SATA_PSTATE_SHUTDOWN flag */ cportinfo->cport_state &= ~(SATA_PSTATE_PWRON | SATA_PSTATE_PWROFF | SATA_PSTATE_FAILED); cportinfo->cport_state |= sata_device->satadev_state & SATA_PSTATE_VALID; } else { sata_pmport_info_t *pmportinfo; if ((sata_device->satadev_addr.qual != SATA_ADDR_PMPORT) || (sata_device->satadev_addr.qual != SATA_ADDR_DPMPORT) || SATA_NUM_PMPORTS(sata_hba_inst, sata_device->satadev_addr.cport) < sata_device->satadev_addr.pmport) return; pmportinfo = SATA_PMPORT_INFO(sata_hba_inst, sata_device->satadev_addr.cport, sata_device->satadev_addr.pmport); sata_update_port_scr(&pmportinfo->pmport_scr, sata_device); /* Preserve SATA_PSTATE_SHUTDOWN flag */ pmportinfo->pmport_state &= ~(SATA_PSTATE_PWRON | SATA_PSTATE_PWROFF | SATA_PSTATE_FAILED); pmportinfo->pmport_state |= sata_device->satadev_state & SATA_PSTATE_VALID; } } /* * Extract SATA port specification from an IOCTL argument. * * This function return the port the user land send us as is, unless it * cannot retrieve port spec, then -1 is returned. * * Note: Only cport - no port multiplier port. */ static int32_t sata_get_port_num(sata_hba_inst_t *sata_hba_inst, struct devctl_iocdata *dcp) { int32_t port; /* Extract port number from nvpair in dca structure */ if (nvlist_lookup_int32(ndi_dc_get_ap_data(dcp), "port", &port) != 0) { SATA_LOG_D((sata_hba_inst, CE_NOTE, "sata_get_port_num: invalid port spec 0x%x in ioctl", port)); port = -1; } return (port); } /* * Get dev_info_t pointer to the device node pointed to by port argument. * NOTE: target argument is a value used in ioctls to identify * the AP - it is not a sata_address. * It is a combination of cport, pmport and address qualifier, encodded same * way as a scsi target number. * At this moment it carries only cport number. * * No PMult hotplug support. * * Returns dev_info_t pointer if target device was found, NULL otherwise. */ static dev_info_t * sata_get_target_dip(dev_info_t *dip, int32_t port) { dev_info_t *cdip = NULL; int target, tgt; int ncport; int circ; ncport = port & SATA_CFGA_CPORT_MASK; target = SATA_TO_SCSI_TARGET(ncport, 0, SATA_ADDR_DCPORT); ndi_devi_enter(dip, &circ); for (cdip = ddi_get_child(dip); cdip != NULL; ) { dev_info_t *next = ddi_get_next_sibling(cdip); tgt = ddi_prop_get_int(DDI_DEV_T_ANY, cdip, DDI_PROP_DONTPASS, "target", -1); if (tgt == -1) { /* * This is actually an error condition, but not * a fatal one. Just continue the search. */ cdip = next; continue; } if (tgt == target) break; cdip = next; } ndi_devi_exit(dip, circ); return (cdip); } /* * sata_cfgadm_state: * Use the sata port state and state of the target node to figure out * the cfgadm_state. * * The port argument is a value with encoded cport, * pmport and address qualifier, in the same manner as a scsi target number. * SCSI_TO_SATA_CPORT macro extracts cport number, * SCSI_TO_SATA_PMPORT extracts pmport number and * SCSI_TO_SATA_ADDR_QUAL extracts port mulitplier qualifier flag. * * For now, support is for cports only - no pmultiplier ports. */ static void sata_cfgadm_state(sata_hba_inst_t *sata_hba_inst, int32_t port, devctl_ap_state_t *ap_state) { uint16_t cport; int port_state; /* Cport only */ cport = SCSI_TO_SATA_CPORT(port); port_state = SATA_CPORT_STATE(sata_hba_inst, cport); if (port_state & SATA_PSTATE_SHUTDOWN || port_state & SATA_PSTATE_FAILED) { ap_state->ap_rstate = AP_RSTATE_DISCONNECTED; ap_state->ap_ostate = AP_OSTATE_UNCONFIGURED; if (port_state & SATA_PSTATE_FAILED) ap_state->ap_condition = AP_COND_FAILED; else ap_state->ap_condition = AP_COND_UNKNOWN; return; } /* Need to check pmult device port here as well, when supported */ /* Port is enabled and ready */ switch (SATA_CPORT_DEV_TYPE(sata_hba_inst, cport)) { case SATA_DTYPE_NONE: { /* No device attached */ ap_state->ap_rstate = AP_RSTATE_EMPTY; ap_state->ap_ostate = AP_OSTATE_UNCONFIGURED; ap_state->ap_condition = AP_COND_OK; break; } case SATA_DTYPE_UNKNOWN: case SATA_DTYPE_ATAPINONCD: case SATA_DTYPE_PMULT: /* Until PMult is supported */ { /* Unknown device attached */ ap_state->ap_rstate = AP_RSTATE_CONNECTED; ap_state->ap_ostate = AP_OSTATE_UNCONFIGURED; ap_state->ap_condition = AP_COND_UNKNOWN; break; } case SATA_DTYPE_ATADISK: case SATA_DTYPE_ATAPICD: { dev_info_t *tdip = NULL; dev_info_t *dip = NULL; int circ; dip = SATA_DIP(sata_hba_inst); tdip = sata_get_target_dip(dip, port); ap_state->ap_rstate = AP_RSTATE_CONNECTED; if (tdip != NULL) { ndi_devi_enter(dip, &circ); mutex_enter(&(DEVI(tdip)->devi_lock)); if ((DEVI_IS_DEVICE_OFFLINE(tdip)) || (DEVI_IS_DEVICE_DOWN(tdip))) { ap_state->ap_ostate = AP_OSTATE_UNCONFIGURED; } else { ap_state->ap_ostate = AP_OSTATE_CONFIGURED; } ap_state->ap_condition = AP_COND_OK; mutex_exit(&(DEVI(tdip)->devi_lock)); ndi_devi_exit(dip, circ); } else { ap_state->ap_ostate = AP_OSTATE_UNCONFIGURED; ap_state->ap_condition = AP_COND_UNKNOWN; } break; } default: ap_state->ap_rstate = AP_RSTATE_CONNECTED; ap_state->ap_ostate = AP_OSTATE_UNCONFIGURED; ap_state->ap_condition = AP_COND_UNKNOWN; /* * This is actually internal error condition (non fatal), * beacuse we already checked all defined device types. */ SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_cfgadm_state: Internal error: " "unknown device type")); break; } } /* * Start or terminate the thread, depending on flag arg and current state */ static void sata_event_thread_control(int startstop) { static int sata_event_thread_terminating = 0; static int sata_event_thread_starting = 0; int i; mutex_enter(&sata_event_mutex); if (startstop == 0 && (sata_event_thread_starting == 1 || sata_event_thread_terminating == 1)) { mutex_exit(&sata_event_mutex); return; } if (startstop == 1 && sata_event_thread_starting == 1) { mutex_exit(&sata_event_mutex); return; } if (startstop == 1 && sata_event_thread_terminating == 1) { sata_event_thread_starting = 1; /* wait til terminate operation completes */ i = SATA_EVNT_DAEMON_TERM_WAIT/SATA_EVNT_DAEMON_TERM_TIMEOUT; while (sata_event_thread_terminating == 1) { if (i-- <= 0) { sata_event_thread_starting = 0; mutex_exit(&sata_event_mutex); #ifdef SATA_DEBUG cmn_err(CE_WARN, "sata_event_thread_control: " "timeout waiting for thread to terminate"); #endif return; } mutex_exit(&sata_event_mutex); delay(drv_usectohz(SATA_EVNT_DAEMON_TERM_TIMEOUT)); mutex_enter(&sata_event_mutex); } } if (startstop == 1) { if (sata_event_thread == NULL) { sata_event_thread = thread_create(NULL, 0, (void (*)())sata_event_daemon, &sata_hba_list, 0, &p0, TS_RUN, minclsyspri); } sata_event_thread_starting = 0; mutex_exit(&sata_event_mutex); return; } /* * If we got here, thread may need to be terminated */ if (sata_event_thread != NULL) { int i; /* Signal event thread to go away */ sata_event_thread_terminating = 1; sata_event_thread_terminate = 1; cv_signal(&sata_event_cv); /* * Wait til daemon terminates. */ i = SATA_EVNT_DAEMON_TERM_WAIT/SATA_EVNT_DAEMON_TERM_TIMEOUT; while (sata_event_thread_terminate == 1) { mutex_exit(&sata_event_mutex); if (i-- <= 0) { /* Daemon did not go away !!! */ #ifdef SATA_DEBUG cmn_err(CE_WARN, "sata_event_thread_control: " "cannot terminate event daemon thread"); #endif mutex_enter(&sata_event_mutex); break; } delay(drv_usectohz(SATA_EVNT_DAEMON_TERM_TIMEOUT)); mutex_enter(&sata_event_mutex); } sata_event_thread_terminating = 0; } ASSERT(sata_event_thread_terminating == 0); ASSERT(sata_event_thread_starting == 0); mutex_exit(&sata_event_mutex); } /* * Log sata message * dev pathname msg line preceeds the logged message. */ static void sata_log(sata_hba_inst_t *sata_hba_inst, uint_t level, char *fmt, ...) { char pathname[128]; dev_info_t *dip; va_list ap; mutex_enter(&sata_log_mutex); va_start(ap, fmt); (void) vsprintf(sata_log_buf, fmt, ap); va_end(ap); if (sata_hba_inst != NULL) { dip = SATA_DIP(sata_hba_inst); (void) ddi_pathname(dip, pathname); } else { pathname[0] = 0; } if (level == CE_CONT) { if (sata_debug_flags == 0) cmn_err(level, "?%s:\n %s\n", pathname, sata_log_buf); else cmn_err(level, "%s:\n %s\n", pathname, sata_log_buf); } else cmn_err(level, "%s:\n %s", pathname, sata_log_buf); mutex_exit(&sata_log_mutex); } /* ******** Asynchronous HBA events handling & hotplugging support ******** */ /* * SATA HBA event notification function. * Events reported by SATA HBA drivers per HBA instance relate to a change in * a port and/or device state or a controller itself. * Events for different addresses/addr types cannot be combined. * A warning message is generated for each event type. * Events are not processed by this function, so only the * event flag(s)is set for an affected entity and the event thread is * waken up. Event daemon thread processes all events. * * NOTE: Since more than one event may be reported at the same time, one * cannot determine a sequence of events when opposite event are reported, eg. * LINK_LOST and LINK_ESTABLISHED. Actual port status during event processing * is taking precedence over reported events, i.e. may cause ignoring some * events. */ #define SATA_EVENT_MAX_MSG_LENGTH 79 void sata_hba_event_notify(dev_info_t *dip, sata_device_t *sata_device, int event) { sata_hba_inst_t *sata_hba_inst = NULL; sata_address_t *saddr; sata_drive_info_t *sdinfo; sata_port_stats_t *pstats; int cport, pmport; char buf1[SATA_EVENT_MAX_MSG_LENGTH + 1]; char buf2[SATA_EVENT_MAX_MSG_LENGTH + 1]; char *lcp; static char *err_msg_evnt_1 = "sata_hba_event_notify: invalid port event 0x%x "; static char *err_msg_evnt_2 = "sata_hba_event_notify: invalid device event 0x%x "; int linkevent; /* * There is a possibility that an event will be generated on HBA * that has not completed attachment or is detaching. * HBA driver should prevent this, but just in case it does not, * we need to ignore events for such HBA. */ mutex_enter(&sata_mutex); for (sata_hba_inst = sata_hba_list; sata_hba_inst != NULL; sata_hba_inst = sata_hba_inst->satahba_next) { if (SATA_DIP(sata_hba_inst) == dip) if (sata_hba_inst->satahba_attached == 1) break; } mutex_exit(&sata_mutex); if (sata_hba_inst == NULL) /* HBA not attached */ return; ASSERT(sata_device != NULL); /* * Validate address before - do not proceed with invalid address. */ saddr = &sata_device->satadev_addr; if (saddr->cport >= SATA_NUM_CPORTS(sata_hba_inst)) return; if (saddr->qual == SATA_ADDR_PMPORT || saddr->qual == SATA_ADDR_DPMPORT) /* Port Multiplier not supported yet */ return; cport = saddr->cport; pmport = saddr->pmport; buf1[0] = buf2[0] = '\0'; /* * Events refer to devices, ports and controllers - each has * unique address. Events for different addresses cannot be combined. */ if (saddr->qual & (SATA_ADDR_CPORT | SATA_ADDR_PMPORT)) { mutex_enter(&(SATA_CPORT_MUTEX(sata_hba_inst, cport))); /* qualify this event(s) */ if ((event & SATA_EVNT_PORT_EVENTS) == 0) { /* Invalid event for the device port */ (void) sprintf(buf2, err_msg_evnt_1, event & SATA_EVNT_PORT_EVENTS); mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, cport))); goto event_info; } if (saddr->qual == SATA_ADDR_CPORT) { /* Controller's device port event */ (SATA_CPORT_INFO(sata_hba_inst, cport))-> cport_event_flags |= event & SATA_EVNT_PORT_EVENTS; pstats = &(SATA_CPORT_INFO(sata_hba_inst, cport))-> cport_stats; } else { /* Port multiplier's device port event */ (SATA_PMPORT_INFO(sata_hba_inst, cport, pmport))-> pmport_event_flags |= event & SATA_EVNT_PORT_EVENTS; pstats = &(SATA_PMPORT_INFO(sata_hba_inst, cport, pmport))-> pmport_stats; } /* * Add to statistics and log the message. We have to do it * here rather than in the event daemon, because there may be * multiple events occuring before they are processed. */ linkevent = event & (SATA_EVNT_LINK_LOST | SATA_EVNT_LINK_ESTABLISHED); if (linkevent) { if (linkevent == (SATA_EVNT_LINK_LOST | SATA_EVNT_LINK_ESTABLISHED)) { /* This is likely event combination */ (void) strlcat(buf1, "link lost/established, ", SATA_EVENT_MAX_MSG_LENGTH); if (pstats->link_lost < 0xffffffffffffffff) pstats->link_lost++; if (pstats->link_established < 0xffffffffffffffff) pstats->link_established++; linkevent = 0; } else if (linkevent & SATA_EVNT_LINK_LOST) { (void) strlcat(buf1, "link lost, ", SATA_EVENT_MAX_MSG_LENGTH); if (pstats->link_lost < 0xffffffffffffffff) pstats->link_lost++; } else { (void) strlcat(buf1, "link established, ", SATA_EVENT_MAX_MSG_LENGTH); if (pstats->link_established < 0xffffffffffffffff) pstats->link_established++; } } if (event & SATA_EVNT_DEVICE_ATTACHED) { (void) strlcat(buf1, "device attached, ", SATA_EVENT_MAX_MSG_LENGTH); if (pstats->device_attached < 0xffffffffffffffff) pstats->device_attached++; } if (event & SATA_EVNT_DEVICE_DETACHED) { (void) strlcat(buf1, "device detached, ", SATA_EVENT_MAX_MSG_LENGTH); if (pstats->device_detached < 0xffffffffffffffff) pstats->device_detached++; } if (event & SATA_EVNT_PWR_LEVEL_CHANGED) { SATADBG1(SATA_DBG_EVENTS, sata_hba_inst, "port %d power level changed", cport); if (pstats->port_pwr_changed < 0xffffffffffffffff) pstats->port_pwr_changed++; } if ((event & ~SATA_EVNT_PORT_EVENTS) != 0) { /* There should be no other events for this address */ (void) sprintf(buf2, err_msg_evnt_1, event & ~SATA_EVNT_PORT_EVENTS); } mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, cport))); } else if (saddr->qual & (SATA_ADDR_DCPORT | SATA_ADDR_DPMPORT)) { mutex_enter(&(SATA_CPORT_MUTEX(sata_hba_inst, cport))); /* qualify this event */ if ((event & SATA_EVNT_DEVICE_RESET) == 0) { /* Invalid event for a device */ (void) sprintf(buf2, err_msg_evnt_2, event & SATA_EVNT_DEVICE_RESET); mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, cport))); goto event_info; } /* drive event */ sdinfo = sata_get_device_info(sata_hba_inst, sata_device); if (sdinfo != NULL) { if (event & SATA_EVNT_DEVICE_RESET) { (void) strlcat(buf1, "device reset, ", SATA_EVENT_MAX_MSG_LENGTH); if (sdinfo->satadrv_stats.drive_reset < 0xffffffffffffffff) sdinfo->satadrv_stats.drive_reset++; sdinfo->satadrv_event_flags |= SATA_EVNT_DEVICE_RESET; } } if ((event & ~SATA_EVNT_DEVICE_RESET) != 0) { /* Invalid event for a device */ (void) sprintf(buf2, err_msg_evnt_2, event & ~SATA_EVNT_DRIVE_EVENTS); } mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, cport))); } else { if (saddr->qual != SATA_ADDR_NULL) { /* Wrong address qualifier */ SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_hba_event_notify: invalid address 0x%x", *(uint32_t *)saddr)); return; } if ((event & SATA_EVNT_CONTROLLER_EVENTS) == 0 || (event & ~SATA_EVNT_CONTROLLER_EVENTS) != 0) { /* Invalid event for the controller */ SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_hba_event_notify: invalid event 0x%x for " "controller", event & SATA_EVNT_CONTROLLER_EVENTS)); return; } buf1[0] = '\0'; /* This may be a frequent and not interesting event */ SATADBG1(SATA_DBG_EVENTS, sata_hba_inst, "controller power level changed\n", NULL); mutex_enter(&sata_hba_inst->satahba_mutex); if (sata_hba_inst->satahba_stats.ctrl_pwr_change < 0xffffffffffffffff) sata_hba_inst->satahba_stats.ctrl_pwr_change++; sata_hba_inst->satahba_event_flags |= SATA_EVNT_PWR_LEVEL_CHANGED; mutex_exit(&sata_hba_inst->satahba_mutex); } /* * If we got here, there is something to do with this HBA * instance. */ mutex_enter(&sata_hba_inst->satahba_mutex); sata_hba_inst->satahba_event_flags |= SATA_EVNT_MAIN; mutex_exit(&sata_hba_inst->satahba_mutex); mutex_enter(&sata_mutex); sata_event_pending |= SATA_EVNT_MAIN; /* global event indicator */ mutex_exit(&sata_mutex); /* Tickle event thread */ mutex_enter(&sata_event_mutex); if (sata_event_thread_active == 0) cv_signal(&sata_event_cv); mutex_exit(&sata_event_mutex); event_info: if (buf1[0] != '\0') { lcp = strrchr(buf1, ','); if (lcp != NULL) *lcp = '\0'; } if (saddr->qual == SATA_ADDR_CPORT || saddr->qual == SATA_ADDR_DCPORT) { if (buf1[0] != '\0') { sata_log(sata_hba_inst, CE_NOTE, "port %d: %s\n", cport, buf1); } if (buf2[0] != '\0') { sata_log(sata_hba_inst, CE_NOTE, "port %d: %s\n", cport, buf2); } } else if (saddr->qual == SATA_ADDR_PMPORT || saddr->qual == SATA_ADDR_DPMPORT) { if (buf1[0] != '\0') { sata_log(sata_hba_inst, CE_NOTE, "port %d pmport %d: %s\n", cport, pmport, buf1); } if (buf2[0] != '\0') { sata_log(sata_hba_inst, CE_NOTE, "port %d pmport %d: %s\n", cport, pmport, buf2); } } } /* * Event processing thread. * Arg is a pointer to the sata_hba_list pointer. * It is not really needed, because sata_hba_list is global and static */ static void sata_event_daemon(void *arg) { #ifndef __lock_lint _NOTE(ARGUNUSED(arg)) #endif sata_hba_inst_t *sata_hba_inst; clock_t lbolt; SATADBG1(SATA_DBG_EVENTS_DAEMON, NULL, "SATA event daemon started\n", NULL); loop: /* * Process events here. Walk through all registered HBAs */ mutex_enter(&sata_mutex); for (sata_hba_inst = sata_hba_list; sata_hba_inst != NULL; sata_hba_inst = sata_hba_inst->satahba_next) { ASSERT(sata_hba_inst != NULL); mutex_enter(&sata_hba_inst->satahba_mutex); if (sata_hba_inst->satahba_attached != 1 || (sata_hba_inst->satahba_event_flags & SATA_EVNT_SKIP) != 0) { mutex_exit(&sata_hba_inst->satahba_mutex); continue; } if (sata_hba_inst->satahba_event_flags & SATA_EVNT_MAIN) { sata_hba_inst->satahba_event_flags |= SATA_EVNT_SKIP; mutex_exit(&sata_hba_inst->satahba_mutex); mutex_exit(&sata_mutex); /* Got the controller with pending event */ sata_process_controller_events(sata_hba_inst); /* * Since global mutex was released, there is a * possibility that HBA list has changed, so start * over from the top. Just processed controller * will be passed-over because of the SKIP flag. */ goto loop; } mutex_exit(&sata_hba_inst->satahba_mutex); } /* Clear SKIP flag in all controllers */ for (sata_hba_inst = sata_hba_list; sata_hba_inst != NULL; sata_hba_inst = sata_hba_inst->satahba_next) { mutex_enter(&sata_hba_inst->satahba_mutex); sata_hba_inst->satahba_event_flags &= ~SATA_EVNT_SKIP; mutex_exit(&sata_hba_inst->satahba_mutex); } mutex_exit(&sata_mutex); SATADBG1(SATA_DBG_EVENTS_DAEMON, NULL, "SATA EVENT DAEMON suspending itself", NULL); #ifdef SATA_DEBUG if ((sata_func_enable & SATA_ENABLE_PROCESS_EVENTS) == 0) { sata_log(sata_hba_inst, CE_WARN, "SATA EVENTS PROCESSING DISABLED\n"); thread_exit(); /* Daemon will not run again */ } #endif mutex_enter(&sata_event_mutex); sata_event_thread_active = 0; mutex_exit(&sata_event_mutex); /* * Go to sleep/suspend itself and wake up either because new event or * wait timeout. Exit if there is a termination request (driver * unload). */ do { lbolt = ddi_get_lbolt(); lbolt += drv_usectohz(SATA_EVNT_DAEMON_SLEEP_TIME); mutex_enter(&sata_event_mutex); (void) cv_timedwait(&sata_event_cv, &sata_event_mutex, lbolt); if (sata_event_thread_active != 0) { mutex_exit(&sata_event_mutex); continue; } /* Check if it is time to go away */ if (sata_event_thread_terminate == 1) { /* * It is up to the thread setting above flag to make * sure that this thread is not killed prematurely. */ sata_event_thread_terminate = 0; sata_event_thread = NULL; mutex_exit(&sata_event_mutex); SATADBG1(SATA_DBG_EVENTS_DAEMON, NULL, "SATA_EVENT_DAEMON_TERMINATING", NULL); thread_exit(); { _NOTE(NOT_REACHED) } } mutex_exit(&sata_event_mutex); } while (!(sata_event_pending & SATA_EVNT_MAIN)); mutex_enter(&sata_event_mutex); sata_event_thread_active = 1; mutex_exit(&sata_event_mutex); mutex_enter(&sata_mutex); sata_event_pending &= ~SATA_EVNT_MAIN; mutex_exit(&sata_mutex); SATADBG1(SATA_DBG_EVENTS_DAEMON, NULL, "SATA EVENT DAEMON READY TO PROCESS EVENT", NULL); goto loop; } /* * Specific HBA instance event processing. * * NOTE: At the moment, device event processing is limited to hard disks * only. * cports only are supported - no pmports. */ static void sata_process_controller_events(sata_hba_inst_t *sata_hba_inst) { int ncport; uint32_t event_flags; sata_address_t *saddr; SATADBG1(SATA_DBG_EVENTS_CNTRL, sata_hba_inst, "Processing controller %d event(s)", ddi_get_instance(SATA_DIP(sata_hba_inst))); mutex_enter(&sata_hba_inst->satahba_mutex); sata_hba_inst->satahba_event_flags &= ~SATA_EVNT_MAIN; event_flags = sata_hba_inst->satahba_event_flags; mutex_exit(&sata_hba_inst->satahba_mutex); /* * Process controller power change first * HERE */ if (event_flags & SATA_EVNT_PWR_LEVEL_CHANGED) sata_process_cntrl_pwr_level_change(sata_hba_inst); /* * Search through ports/devices to identify affected port/device. * We may have to process events for more than one port/device. */ for (ncport = 0; ncport < SATA_NUM_CPORTS(sata_hba_inst); ncport++) { mutex_enter(&(SATA_CPORT_MUTEX(sata_hba_inst, ncport))); event_flags = (SATA_CPORT_INFO(sata_hba_inst, ncport))-> cport_event_flags; /* Check if port was locked by IOCTL processing */ if (event_flags & SATA_APCTL_LOCK_PORT_BUSY) { /* * We ignore port events because port is busy * with AP control processing. Set again * controller and main event flag, so that * events may be processed by the next daemon * run. */ mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, ncport))); mutex_enter(&sata_hba_inst->satahba_mutex); sata_hba_inst->satahba_event_flags |= SATA_EVNT_MAIN; mutex_exit(&sata_hba_inst->satahba_mutex); mutex_enter(&sata_mutex); sata_event_pending |= SATA_EVNT_MAIN; mutex_exit(&sata_mutex); SATADBG1(SATA_DBG_EVENTS_PROCPST, sata_hba_inst, "Event processing postponed until " "AP control processing completes", NULL); /* Check other ports */ continue; } else { /* * Set BSY flag so that AP control would not * interfere with events processing for * this port. */ (SATA_CPORT_INFO(sata_hba_inst, ncport))-> cport_event_flags |= SATA_EVNT_LOCK_PORT_BUSY; } mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, ncport))); saddr = &(SATA_CPORT_INFO(sata_hba_inst, ncport))->cport_addr; if ((event_flags & (SATA_EVNT_PORT_EVENTS | SATA_EVNT_DRIVE_EVENTS)) != 0) { /* * Got port event. * We need some hierarchy of event processing as they * are affecting each other: * 1. port failed * 2. device detached/attached * 3. link events - link events may trigger device * detached or device attached events in some * circumstances. * 4. port power level changed */ if (event_flags & SATA_EVNT_PORT_FAILED) { sata_process_port_failed_event(sata_hba_inst, saddr); } if (event_flags & SATA_EVNT_DEVICE_DETACHED) { sata_process_device_detached(sata_hba_inst, saddr); } if (event_flags & SATA_EVNT_DEVICE_ATTACHED) { sata_process_device_attached(sata_hba_inst, saddr); } if (event_flags & (SATA_EVNT_LINK_ESTABLISHED | SATA_EVNT_LINK_LOST)) { sata_process_port_link_events(sata_hba_inst, saddr); } if (event_flags & SATA_EVNT_PWR_LEVEL_CHANGED) { sata_process_port_pwr_change(sata_hba_inst, saddr); } } if (SATA_CPORT_DEV_TYPE(sata_hba_inst, ncport) != SATA_DTYPE_NONE) { /* May have device event */ sata_process_device_reset(sata_hba_inst, saddr); } mutex_enter(&(SATA_CPORT_MUTEX(sata_hba_inst, ncport))); /* Release PORT_BUSY flag */ (SATA_CPORT_INFO(sata_hba_inst, ncport))-> cport_event_flags &= ~SATA_EVNT_LOCK_PORT_BUSY; mutex_exit(&(SATA_CPORT_MUTEX(sata_hba_inst, ncport))); } /* End of loop through the controller SATA ports */ } /* * Process HBA power level change reported by HBA driver. * Not implemented at this time - event is ignored. */ static void sata_process_cntrl_pwr_level_change(sata_hba_inst_t *sata_hba_inst) { SATADBG1(SATA_DBG_EVENTS_PROC, sata_hba_inst, "Processing controller power level change", NULL); /* Ignoring it for now */ mutex_enter(&sata_hba_inst->satahba_mutex); sata_hba_inst->satahba_event_flags &= ~SATA_EVNT_PWR_LEVEL_CHANGED; mutex_exit(&sata_hba_inst->satahba_mutex); } /* * Process port power level change reported by HBA driver. * Not implemented at this time - event is ignored. */ static void sata_process_port_pwr_change(sata_hba_inst_t *sata_hba_inst, sata_address_t *saddr) { sata_cport_info_t *cportinfo; SATADBG1(SATA_DBG_EVENTS_PROC, sata_hba_inst, "Processing port power level change", NULL); cportinfo = SATA_CPORT_INFO(sata_hba_inst, saddr->cport); mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); /* Reset event flag */ cportinfo->cport_event_flags &= ~SATA_EVNT_PWR_LEVEL_CHANGED; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); } /* * Process port failure reported by HBA driver. * cports support only - no pmports. */ static void sata_process_port_failed_event(sata_hba_inst_t *sata_hba_inst, sata_address_t *saddr) { sata_cport_info_t *cportinfo; cportinfo = SATA_CPORT_INFO(sata_hba_inst, saddr->cport); mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); /* Reset event flag first */ cportinfo->cport_event_flags &= ~SATA_EVNT_PORT_FAILED; /* If the port is in SHUTDOWN or FAILED state, ignore this event. */ if ((cportinfo->cport_state & (SATA_PSTATE_SHUTDOWN | SATA_PSTATE_FAILED)) == 0) { mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)-> cport_mutex); return; } /* Fail the port */ cportinfo->cport_state = SATA_PSTATE_FAILED; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); sata_log(sata_hba_inst, CE_WARN, "port %d failed", saddr->cport); } /* * Device Reset Event processing. * The seqeunce is managed by 3 stage flags: * - reset event reported, * - reset event being processed, * - request to clear device reset state. */ static void sata_process_device_reset(sata_hba_inst_t *sata_hba_inst, sata_address_t *saddr) { sata_drive_info_t old_sdinfo; /* local copy of the drive info */ sata_drive_info_t *sdinfo; sata_cport_info_t *cportinfo; sata_device_t sata_device; int rval; /* We only care about host sata cport for now */ cportinfo = SATA_CPORT_INFO(sata_hba_inst, saddr->cport); mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); /* If the port is in SHUTDOWN or FAILED state, ignore reset event. */ if ((cportinfo->cport_state & (SATA_PSTATE_SHUTDOWN | SATA_PSTATE_FAILED)) != 0) { mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)-> cport_mutex); return; } if ((SATA_CPORT_DEV_TYPE(sata_hba_inst, saddr->cport) & SATA_VALID_DEV_TYPE) == 0) { mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)-> cport_mutex); return; } sdinfo = SATA_CPORT_DRV_INFO(sata_hba_inst, saddr->cport); if (sdinfo == NULL) { mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)-> cport_mutex); return; } if ((sdinfo->satadrv_event_flags & SATA_EVNT_DEVICE_RESET) == 0) { /* Nothing to do */ mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)-> cport_mutex); return; } SATADBG1(SATA_DBG_EVENTS_PROC, sata_hba_inst, "Processing port %d device reset", saddr->cport); if (sdinfo->satadrv_event_flags & SATA_EVNT_INPROC_DEVICE_RESET) { /* Something is weird - new device reset event */ SATADBG1(SATA_DBG_EVENTS_PROC, sata_hba_inst, "Overlapping device reset events!", NULL); /* Just leave */ mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)-> cport_mutex); return; } /* Clear event flag */ sdinfo->satadrv_event_flags &= ~SATA_EVNT_DEVICE_RESET; /* It seems that we always need to check the port state first */ sata_device.satadev_rev = SATA_DEVICE_REV; sata_device.satadev_addr = *saddr; /* * We have to exit mutex, because the HBA probe port function may * block on its own mutex. */ mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); rval = (*SATA_PROBE_PORT_FUNC(sata_hba_inst)) (SATA_DIP(sata_hba_inst), &sata_device); mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); sata_update_port_info(sata_hba_inst, &sata_device); if (rval != SATA_SUCCESS) { /* Something went wrong? Fail the port */ cportinfo->cport_state = SATA_PSTATE_FAILED; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)-> cport_mutex); SATA_LOG_D((sata_hba_inst, CE_WARN, "Port %d probing failed", saddr->cport)); return; } if ((sata_device.satadev_scr.sstatus & SATA_PORT_DEVLINK_UP_MASK) != SATA_PORT_DEVLINK_UP || sata_device.satadev_type == SATA_DTYPE_NONE) { /* * No device to process, anymore. Some other event processing * would or have already performed port info cleanup. * To be safe (HBA may need it), request clearing device * reset condition. */ sdinfo->satadrv_event_flags = 0; sdinfo->satadrv_event_flags |= SATA_EVNT_CLEAR_DEVICE_RESET; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)-> cport_mutex); return; } /* Mark device reset processing as active */ sdinfo->satadrv_event_flags |= SATA_EVNT_INPROC_DEVICE_RESET; old_sdinfo = *sdinfo; /* local copy of the drive info */ mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); if (sata_restore_drive_settings(sata_hba_inst, &old_sdinfo) == SATA_FAILURE) { /* * Restoring drive setting failed. * Probe the port first, to check if the port state has changed */ sata_device.satadev_rev = SATA_DEVICE_REV; sata_device.satadev_addr = *saddr; sata_device.satadev_addr.qual = SATA_ADDR_CPORT; /* probe port */ rval = (*SATA_PROBE_PORT_FUNC(sata_hba_inst)) (SATA_DIP(sata_hba_inst), &sata_device); mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)-> cport_mutex); if (rval == SATA_SUCCESS && (sata_device.satadev_state & (SATA_PSTATE_SHUTDOWN | SATA_PSTATE_FAILED)) == 0 && (sata_device.satadev_scr.sstatus & SATA_PORT_DEVLINK_UP_MASK) == SATA_PORT_DEVLINK_UP && (sata_device.satadev_type & SATA_DTYPE_ATADISK) != 0) { /* * We may retry this a bit later - reinstate reset * condition */ if ((cportinfo->cport_dev_type & SATA_VALID_DEV_TYPE) != 0 && SATA_CPORTINFO_DRV_INFO(cportinfo) != NULL) { sdinfo = SATA_CPORTINFO_DRV_INFO(cportinfo); sdinfo->satadrv_event_flags |= SATA_EVNT_DEVICE_RESET; sdinfo->satadrv_event_flags &= ~SATA_EVNT_INPROC_DEVICE_RESET; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); mutex_enter(&sata_hba_inst->satahba_mutex); sata_hba_inst->satahba_event_flags |= SATA_EVNT_MAIN; mutex_exit(&sata_hba_inst->satahba_mutex); return; } } else { /* * No point of retrying - some other event processing * would or already did port info cleanup. * To be safe (HBA may need it), * request clearing device reset condition. */ sdinfo->satadrv_event_flags = 0; sdinfo->satadrv_event_flags |= SATA_EVNT_CLEAR_DEVICE_RESET; } mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)-> cport_mutex); return; } /* * Raise the flag indicating that the next sata command could * be sent with SATA_CLEAR_DEV_RESET_STATE flag, if no new device * reset is reported. */ mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); if ((cportinfo->cport_dev_type & SATA_VALID_DEV_TYPE) != 0 && SATA_CPORTINFO_DRV_INFO(cportinfo) != NULL) { sdinfo = SATA_CPORTINFO_DRV_INFO(cportinfo); sdinfo->satadrv_event_flags &= ~SATA_EVNT_INPROC_DEVICE_RESET; sdinfo->satadrv_event_flags |= SATA_EVNT_CLEAR_DEVICE_RESET; } mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); } /* * Port Link Events processing. * Every link established event may involve device reset (due to * COMRESET signal, equivalent of the hard reset) so arbitrarily * set device reset event for an attached device (if any). * If the port is in SHUTDOWN or FAILED state, ignore link events. * * The link established event processing varies, depending on the state * of the target node, HBA hotplugging capabilities, state of the port. * If the link is not active, the link established event is ignored. * If HBA cannot detect device attachment and there is no target node, * the link established event triggers device attach event processing. * Else, link established event triggers device reset event processing. * * The link lost event processing varies, depending on a HBA hotplugging * capability and the state of the port (link active or not active). * If the link is active, the lost link event is ignored. * If HBA cannot detect device removal, the lost link event triggers * device detached event processing after link lost timeout. * Else, the event is ignored. * * NOTE: Only cports are processed for now, i.e. no port multiplier ports */ static void sata_process_port_link_events(sata_hba_inst_t *sata_hba_inst, sata_address_t *saddr) { sata_device_t sata_device; sata_cport_info_t *cportinfo; sata_drive_info_t *sdinfo; int event_flags; int rval; SATADBG1(SATA_DBG_EVENTS_PROC, sata_hba_inst, "Processing port %d link event(s)", saddr->cport); cportinfo = SATA_CPORT_INFO(sata_hba_inst, saddr->cport); mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); event_flags = cportinfo->cport_event_flags; /* Reset event flags first */ cportinfo->cport_event_flags &= ~(SATA_EVNT_LINK_ESTABLISHED | SATA_EVNT_LINK_LOST); /* If the port is in SHUTDOWN or FAILED state, ignore link events. */ if ((cportinfo->cport_state & (SATA_PSTATE_SHUTDOWN | SATA_PSTATE_FAILED)) != 0) { mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)-> cport_mutex); return; } /* * For the sanity sake get current port state. * Set device address only. Other sata_device fields should be * set by HBA driver. */ sata_device.satadev_rev = SATA_DEVICE_REV; sata_device.satadev_addr = *saddr; /* * We have to exit mutex, because the HBA probe port function may * block on its own mutex. */ mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); rval = (*SATA_PROBE_PORT_FUNC(sata_hba_inst)) (SATA_DIP(sata_hba_inst), &sata_device); mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); sata_update_port_info(sata_hba_inst, &sata_device); if (rval != SATA_SUCCESS) { /* Something went wrong? Fail the port */ cportinfo->cport_state = SATA_PSTATE_FAILED; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)-> cport_mutex); SATA_LOG_D((sata_hba_inst, CE_WARN, "Port %d probing failed", saddr->cport)); /* * We may want to release device info structure, but * it is not necessary. */ return; } else { /* port probed successfully */ cportinfo->cport_state |= SATA_STATE_PROBED | SATA_STATE_READY; } if (event_flags & SATA_EVNT_LINK_ESTABLISHED) { if ((sata_device.satadev_scr.sstatus & SATA_PORT_DEVLINK_UP_MASK) != SATA_PORT_DEVLINK_UP) { /* Ignore event */ SATADBG1(SATA_DBG_EVENTS_PROC, sata_hba_inst, "Ignoring port %d link established event - " "link down", saddr->cport); goto linklost; } SATADBG1(SATA_DBG_EVENTS_PROC, sata_hba_inst, "Processing port %d link established event", saddr->cport); /* * For the sanity sake check if a device is attached - check * return state of a port probing. */ if (sata_device.satadev_type != SATA_DTYPE_NONE && sata_device.satadev_type != SATA_DTYPE_PMULT) { /* * HBA port probe indicated that there is a device * attached. Check if the framework had device info * structure attached for this device. */ if (cportinfo->cport_dev_type != SATA_DTYPE_NONE) { ASSERT(SATA_CPORTINFO_DRV_INFO(cportinfo) != NULL); sdinfo = SATA_CPORTINFO_DRV_INFO(cportinfo); if ((sdinfo->satadrv_type & SATA_VALID_DEV_TYPE) != 0) { /* * Dev info structure is present. * If dev_type is set to known type in * the framework's drive info struct * then the device existed before and * the link was probably lost * momentarily - in such case * we may want to check device * identity. * Identity check is not supported now. * * Link established event * triggers device reset event. */ (SATA_CPORTINFO_DRV_INFO(cportinfo))-> satadrv_event_flags |= SATA_EVNT_DEVICE_RESET; } } else if (cportinfo->cport_dev_type == SATA_DTYPE_NONE) { /* * We got new device attached! If HBA does not * generate device attached events, trigger it * here. */ if (!(SATA_FEATURES(sata_hba_inst) & SATA_CTLF_HOTPLUG)) { cportinfo->cport_event_flags |= SATA_EVNT_DEVICE_ATTACHED; } } /* Reset link lost timeout */ cportinfo->cport_link_lost_time = 0; } } linklost: if (event_flags & SATA_EVNT_LINK_LOST) { if ((sata_device.satadev_scr.sstatus & SATA_PORT_DEVLINK_UP_MASK) == SATA_PORT_DEVLINK_UP) { /* Ignore event */ SATADBG1(SATA_DBG_EVENTS_PROC, sata_hba_inst, "Ignoring port %d link lost event - link is up", saddr->cport); goto done; } #ifdef SATA_DEBUG if (cportinfo->cport_link_lost_time == 0) { SATADBG1(SATA_DBG_EVENTS_PROC, sata_hba_inst, "Processing port %d link lost event", saddr->cport); } #endif /* * When HBA cannot generate device attached/detached events, * we need to track link lost time and eventually generate * device detach event. */ if (!(SATA_FEATURES(sata_hba_inst) & SATA_CTLF_HOTPLUG)) { /* We are tracking link lost time */ if (cportinfo->cport_link_lost_time == 0) { /* save current time (lbolt value) */ cportinfo->cport_link_lost_time = ddi_get_lbolt(); /* just keep link lost event */ cportinfo->cport_event_flags |= SATA_EVNT_LINK_LOST; } else { clock_t cur_time = ddi_get_lbolt(); if ((cur_time - cportinfo->cport_link_lost_time) >= drv_usectohz( SATA_EVNT_LINK_LOST_TIMEOUT)) { /* trigger device detach event */ cportinfo->cport_event_flags |= SATA_EVNT_DEVICE_DETACHED; cportinfo->cport_link_lost_time = 0; SATADBG1(SATA_DBG_EVENTS, sata_hba_inst, "Triggering port %d " "device detached event", saddr->cport); } else { /* keep link lost event */ cportinfo->cport_event_flags |= SATA_EVNT_LINK_LOST; } } } /* * We could change port state to disable/delay access to * the attached device until the link is recovered. */ } done: event_flags = cportinfo->cport_event_flags; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); if (event_flags != 0) { mutex_enter(&sata_hba_inst->satahba_mutex); sata_hba_inst->satahba_event_flags |= SATA_EVNT_MAIN; mutex_exit(&sata_hba_inst->satahba_mutex); mutex_enter(&sata_mutex); sata_event_pending |= SATA_EVNT_MAIN; mutex_exit(&sata_mutex); } } /* * Device Detached Event processing. * Port is probed to find if a device is really gone. If so, * the device info structure is detached from the SATA port info structure * and released. * Port status is updated. * * NOTE: Process cports event only, no port multiplier ports. */ static void sata_process_device_detached(sata_hba_inst_t *sata_hba_inst, sata_address_t *saddr) { sata_cport_info_t *cportinfo; sata_drive_info_t *sdevinfo; sata_device_t sata_device; dev_info_t *tdip; int rval; SATADBG1(SATA_DBG_EVENTS_PROC, sata_hba_inst, "Processing port %d device detached", saddr->cport); cportinfo = SATA_CPORT_INFO(sata_hba_inst, saddr->cport); mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); /* Clear event flag */ cportinfo->cport_event_flags &= ~SATA_EVNT_DEVICE_DETACHED; /* If the port is in SHUTDOWN or FAILED state, ignore detach event. */ if ((cportinfo->cport_state & (SATA_PSTATE_SHUTDOWN | SATA_PSTATE_FAILED)) != 0) { mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)-> cport_mutex); return; } /* For sanity, re-probe the port */ sata_device.satadev_rev = SATA_DEVICE_REV; sata_device.satadev_addr = *saddr; /* * We have to exit mutex, because the HBA probe port function may * block on its own mutex. */ mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); rval = (*SATA_PROBE_PORT_FUNC(sata_hba_inst)) (SATA_DIP(sata_hba_inst), &sata_device); mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); sata_update_port_info(sata_hba_inst, &sata_device); if (rval != SATA_SUCCESS) { /* Something went wrong? Fail the port */ cportinfo->cport_state = SATA_PSTATE_FAILED; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)-> cport_mutex); SATA_LOG_D((sata_hba_inst, CE_WARN, "Port %d probing failed", saddr->cport)); /* * We may want to release device info structure, but * it is not necessary. */ return; } else { /* port probed successfully */ cportinfo->cport_state |= SATA_STATE_PROBED | SATA_STATE_READY; } /* * Check if a device is still attached. For sanity, check also * link status - if no link, there is no device. */ if ((sata_device.satadev_scr.sstatus & SATA_PORT_DEVLINK_UP_MASK) == SATA_PORT_DEVLINK_UP && sata_device.satadev_type != SATA_DTYPE_NONE) { /* * Device is still attached - ignore detach event. */ mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)-> cport_mutex); SATADBG1(SATA_DBG_EVENTS_PROC, sata_hba_inst, "Ignoring detach - device still attached to port %d", sata_device.satadev_addr.cport); return; } /* * We need to detach and release device info structure here */ if (SATA_CPORTINFO_DRV_INFO(cportinfo) != NULL) { sdevinfo = SATA_CPORTINFO_DRV_INFO(cportinfo); SATA_CPORTINFO_DRV_INFO(cportinfo) = NULL; (void) kmem_free((void *)sdevinfo, sizeof (sata_drive_info_t)); } cportinfo->cport_dev_type = SATA_DTYPE_NONE; /* * Device cannot be reached anymore, even if the target node may be * still present. */ mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); sata_log(sata_hba_inst, CE_WARN, "SATA device detached at port %d", sata_device.satadev_addr.cport); /* * Try to offline a device and remove target node if it still exists */ tdip = sata_get_target_dip(SATA_DIP(sata_hba_inst), saddr->cport); if (tdip != NULL) { /* * target node exist - unconfigure device first, then remove * the node */ if (ndi_devi_offline(tdip, NDI_UNCONFIG) != NDI_SUCCESS) { /* * PROBLEM - no device, but target node remained * This happens when the file was open or node was * waiting for resources. */ SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_process_device_detached: " "Failed to unconfigure removed device.")); } if (ndi_devi_offline(tdip, NDI_DEVI_REMOVE) != NDI_SUCCESS) { /* * PROBLEM - no device, but target node remained * This happens when the file was open or node was * waiting for resources. */ SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_process_device_detached: " "Failed to remove target node for " "removed device.")); } } /* * Generate sysevent - EC_DR / ESC_DR_AP_STATE_CHANGE * with the hint: SE_HINT_REMOVE */ sata_gen_sysevent(sata_hba_inst, saddr, SE_HINT_REMOVE); } /* * Device Attached Event processing. * Port state is checked to verify that a device is really attached. If so, * the device info structure is created and attached to the SATA port info * structure. * * This function cannot be called in interrupt context (it may sleep). * * NOTE: Process cports event only, no port multiplier ports. */ static void sata_process_device_attached(sata_hba_inst_t *sata_hba_inst, sata_address_t *saddr) { sata_cport_info_t *cportinfo; sata_drive_info_t *sdevinfo; sata_device_t sata_device; dev_info_t *tdip; int rval; SATADBG1(SATA_DBG_EVENTS_PROC, sata_hba_inst, "Processing port %d device attached", saddr->cport); cportinfo = SATA_CPORT_INFO(sata_hba_inst, saddr->cport); mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); /* Clear event flag first */ cportinfo->cport_event_flags &= ~SATA_EVNT_DEVICE_ATTACHED; /* If the port is in SHUTDOWN or FAILED state, ignore event. */ if ((cportinfo->cport_state & (SATA_PSTATE_SHUTDOWN | SATA_PSTATE_FAILED)) != 0) { mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)-> cport_mutex); return; } /* * If the sata_drive_info structure is found attached to the port info, * something went wrong in the event reporting and processing sequence. * To recover, arbitrarily release device info structure and issue * a warning. */ if (SATA_CPORTINFO_DRV_INFO(cportinfo) != NULL) { sdevinfo = SATA_CPORTINFO_DRV_INFO(cportinfo); SATA_CPORTINFO_DRV_INFO(cportinfo) = NULL; (void) kmem_free((void *)sdevinfo, sizeof (sata_drive_info_t)); SATA_LOG_D((sata_hba_inst, CE_WARN, "Arbitrarily detaching old device info.")); } cportinfo->cport_dev_type = SATA_DTYPE_NONE; /* For sanity, re-probe the port */ sata_device.satadev_rev = SATA_DEVICE_REV; sata_device.satadev_addr = *saddr; /* * We have to exit mutex, because the HBA probe port function may * block on its own mutex. */ mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); rval = (*SATA_PROBE_PORT_FUNC(sata_hba_inst)) (SATA_DIP(sata_hba_inst), &sata_device); mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); sata_update_port_info(sata_hba_inst, &sata_device); if (rval != SATA_SUCCESS) { /* Something went wrong? Fail the port */ cportinfo->cport_state = SATA_PSTATE_FAILED; mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)-> cport_mutex); SATA_LOG_D((sata_hba_inst, CE_WARN, "Port %d probing failed", saddr->cport)); return; } else { /* port probed successfully */ cportinfo->cport_state |= SATA_STATE_PROBED | SATA_STATE_READY; } /* * Check if a device is still attached. For sanity, check also * link status - if no link, there is no device. */ if ((sata_device.satadev_scr.sstatus & SATA_PORT_DEVLINK_UP_MASK) != SATA_PORT_DEVLINK_UP || sata_device.satadev_type == SATA_DTYPE_NONE) { /* * No device - ignore attach event. */ mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)-> cport_mutex); SATADBG1(SATA_DBG_EVENTS_PROC, sata_hba_inst, "Ignoring attach - no device connected to port %d", sata_device.satadev_addr.cport); return; } mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); /* * Generate sysevent - EC_DR / ESC_DR_AP_STATE_CHANGE * with the hint: SE_HINT_INSERT */ sata_gen_sysevent(sata_hba_inst, saddr, SE_HINT_INSERT); /* * Make sure that there is no target node for that device. * If so, release it. It should not happen, unless we had problem * removing the node when device was detached. */ tdip = sata_get_target_dip(SATA_DIP(sata_hba_inst), saddr->cport); if (tdip != NULL) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_process_device_attached: " "old device target node exists!!!")); /* * target node exist - unconfigure device first, then remove * the node */ if (ndi_devi_offline(tdip, NDI_UNCONFIG) != NDI_SUCCESS) { /* * PROBLEM - no device, but target node remained * This happens when the file was open or node was * waiting for resources. */ SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_process_device_attached: " "Failed to unconfigure old target node!")); } /* Following call will retry node offlining and removing it */ if (ndi_devi_offline(tdip, NDI_DEVI_REMOVE) != NDI_SUCCESS) { /* PROBLEM - no device, but target node remained */ SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_process_device_attached: " "Failed to remove old target node!")); /* * It is not clear, what should be done here. * For now, we will not attach a new device */ return; } } /* * Reprobing port will take care of the creation of the device info * structure and determination of the device type. */ sata_device.satadev_addr = *saddr; (void) sata_reprobe_port(sata_hba_inst, &sata_device); /* * If device was successfully attached, an explicit * 'configure' command is needed to configure it. */ mutex_enter(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); if ((cportinfo->cport_state & SATA_STATE_READY) && cportinfo->cport_dev_type != SATA_DTYPE_NONE) { sata_log(sata_hba_inst, CE_WARN, "SATA device attached at port %d", saddr->cport); if (SATA_CPORTINFO_DRV_INFO(cportinfo) != NULL) { sata_drive_info_t new_sdinfo; /* Log device info data */ new_sdinfo = *(SATA_CPORTINFO_DRV_INFO(cportinfo)); sata_show_drive_info(sata_hba_inst, &new_sdinfo); } } mutex_exit(&SATA_CPORT_INFO(sata_hba_inst, saddr->cport)->cport_mutex); } /* * sata_restore_drive_settings function compares current device setting * with the saved device setting and, if there is a difference, restores * device setting to the stored state. * Device Identify data has to be current. * At the moment only read ahead and write cache settings are considered. * * This function cannot be called in the interrupt context (it may sleep). * * Returns TRUE if successful or there was nothing to do. * Returns FALSE if device setting could not be restored. * * Note: This function may fail the port, making it inaccessible. * Explicit port disconnect/connect or physical device * detach/attach is required to re-evaluate it's state afterwards */ static int sata_restore_drive_settings(sata_hba_inst_t *sata_hba_inst, sata_drive_info_t *sdinfo) { sata_pkt_t *spkt; sata_cmd_t *scmd; sata_pkt_txlate_t *spx; int rval = SATA_SUCCESS; sata_drive_info_t new_sdinfo; bzero(&new_sdinfo, sizeof (sata_drive_info_t)); new_sdinfo.satadrv_addr = sdinfo->satadrv_addr; new_sdinfo.satadrv_type = sdinfo->satadrv_type; if (sata_fetch_device_identify_data(sata_hba_inst, &new_sdinfo) != 0) { /* * Cannot get device identification - retry later */ SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_restore_drive_settings: " "cannot fetch device identify data\n")); return (SATA_FAILURE); } /* Arbitrarily set UDMA mode */ if (sata_set_udma_mode(sata_hba_inst, &new_sdinfo) != SATA_SUCCESS) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_restore_drive_settings: cannot set UDMA mode\n")); return (SATA_FAILURE); } if (!(new_sdinfo.satadrv_id.ai_cmdset82 & SATA_LOOK_AHEAD) && !(new_sdinfo.satadrv_id.ai_cmdset82 & SATA_WRITE_CACHE)) { /* None of the features is supported - do nothing */ SATADBG1(SATA_DBG_EVENTS_PROC, sata_hba_inst, "restorable features not supported\n", NULL); return (SATA_SUCCESS); } if (((new_sdinfo.satadrv_id.ai_features85 & SATA_LOOK_AHEAD) && (sdinfo->satadrv_settings & SATA_DEV_READ_AHEAD)) && ((new_sdinfo.satadrv_id.ai_features85 & SATA_WRITE_CACHE) && (sdinfo->satadrv_settings & SATA_DEV_WRITE_CACHE))) { /* Nothing to do */ SATADBG1(SATA_DBG_EVENTS_PROC, sata_hba_inst, "nothing to restore\n", NULL); return (SATA_SUCCESS); } /* Prepare packet for SET FEATURES COMMAND */ spx = kmem_zalloc(sizeof (sata_pkt_txlate_t), KM_SLEEP); spx->txlt_sata_hba_inst = sata_hba_inst; spx->txlt_scsi_pkt = NULL; /* No scsi pkt involved */ spkt = sata_pkt_alloc(spx, SLEEP_FUNC); if (spkt == NULL) { kmem_free(spx, sizeof (sata_pkt_txlate_t)); SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_restore_drive_settings: could not " "restore device settings\n")); return (SATA_FAILURE); } /* Fill sata_pkt */ spkt->satapkt_device.satadev_addr = sdinfo->satadrv_addr; /* Timeout 30s */ spkt->satapkt_time = sata_default_pkt_time; /* Synchronous mode, no callback */ spkt->satapkt_op_mode = SATA_OPMODE_SYNCH | SATA_OPMODE_INTERRUPTS; spkt->satapkt_comp = NULL; scmd = &spkt->satapkt_cmd; scmd->satacmd_flags.sata_data_direction = SATA_DIR_NODATA_XFER; scmd->satacmd_flags.sata_ignore_dev_reset = B_TRUE; scmd->satacmd_addr_type = 0; scmd->satacmd_device_reg = 0; scmd->satacmd_status_reg = 0; scmd->satacmd_error_reg = 0; scmd->satacmd_cmd_reg = SATAC_SET_FEATURES; if (!((new_sdinfo.satadrv_id.ai_features85 & SATA_LOOK_AHEAD) && (sdinfo->satadrv_settings & SATA_DEV_READ_AHEAD))) { if (sdinfo->satadrv_settings & SATA_DEV_READ_AHEAD) /* Enable read ahead / read cache */ scmd->satacmd_features_reg = SATAC_SF_ENABLE_READ_AHEAD; else /* Disable read ahead / read cache */ scmd->satacmd_features_reg = SATAC_SF_DISABLE_READ_AHEAD; /* Transfer command to HBA */ if (((*SATA_START_FUNC(sata_hba_inst)) (SATA_DIP(sata_hba_inst), spkt) != 0) || (spkt->satapkt_reason != SATA_PKT_COMPLETED)) { /* Pkt execution failed */ SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_restore_drive_settings: could not " "restore device settings\n")); rval = SATA_FAILURE; } } /* Note that the sata packet is not removed, so it could be re-used */ if (!((new_sdinfo.satadrv_id.ai_features85 & SATA_WRITE_CACHE) && (sdinfo->satadrv_settings & SATA_DEV_WRITE_CACHE))) { if (sdinfo->satadrv_settings & SATA_DEV_WRITE_CACHE) /* Enable write cache */ scmd->satacmd_features_reg = SATAC_SF_ENABLE_WRITE_CACHE; else /* Disable write cache */ scmd->satacmd_features_reg = SATAC_SF_DISABLE_WRITE_CACHE; /* Transfer command to HBA */ if (((*SATA_START_FUNC(sata_hba_inst))( SATA_DIP(sata_hba_inst), spkt) != 0) || (spkt->satapkt_reason != SATA_PKT_COMPLETED)) { /* Pkt execution failed */ SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_restore_drive_settings: could not " "restore device settings\n")); rval = SATA_FAILURE; } } /* Free allocated resources */ sata_pkt_free(spx); (void) kmem_free(spx, sizeof (sata_pkt_txlate_t)); /* * We need to fetch Device Identify data again */ if (sata_fetch_device_identify_data(sata_hba_inst, &new_sdinfo) != 0) { /* * Cannot get device identification - retry later */ SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_restore_drive_settings: " "cannot re-fetch device identify data\n")); rval = SATA_FAILURE; } /* Copy device sata info. */ sdinfo->satadrv_id = new_sdinfo.satadrv_id; return (rval); } /* * * Returns 1 if threshold exceeded, 0 if threshold no exceeded, -1 if * unable to determine. * * Cannot be called in an interrupt context. * * Called by sata_build_lsense_page_2f() */ static int sata_fetch_smart_return_status(sata_hba_inst_t *sata_hba_inst, sata_drive_info_t *sdinfo) { sata_pkt_t *spkt; sata_cmd_t *scmd; sata_pkt_txlate_t *spx; int rval; spx = kmem_zalloc(sizeof (sata_pkt_txlate_t), KM_SLEEP); spx->txlt_sata_hba_inst = sata_hba_inst; spx->txlt_scsi_pkt = NULL; /* No scsi pkt involved */ spkt = sata_pkt_alloc(spx, SLEEP_FUNC); if (spkt == NULL) { kmem_free(spx, sizeof (sata_pkt_txlate_t)); return (-1); } /* address is needed now */ spkt->satapkt_device.satadev_addr = sdinfo->satadrv_addr; /* Fill sata_pkt */ spkt->satapkt_device.satadev_addr = sdinfo->satadrv_addr; spkt->satapkt_op_mode = SATA_OPMODE_SYNCH | SATA_OPMODE_INTERRUPTS; /* Synchronous mode, no callback */ spkt->satapkt_comp = NULL; /* Timeout 30s */ spkt->satapkt_time = sata_default_pkt_time; scmd = &spkt->satapkt_cmd; scmd->satacmd_flags.sata_special_regs = B_TRUE; scmd->satacmd_flags.sata_data_direction = SATA_DIR_NODATA_XFER; /* Set up which registers need to be returned */ scmd->satacmd_flags.sata_copy_out_lba_mid_lsb = B_TRUE; scmd->satacmd_flags.sata_copy_out_lba_high_lsb = B_TRUE; /* Build SMART_RETURN_STATUS cmd in the sata_pkt */ scmd->satacmd_addr_type = 0; /* N/A */ scmd->satacmd_sec_count_lsb = 0; /* N/A */ scmd->satacmd_lba_low_lsb = 0; /* N/A */ scmd->satacmd_lba_mid_lsb = SMART_MAGIC_VAL_1; scmd->satacmd_lba_high_lsb = SMART_MAGIC_VAL_2; scmd->satacmd_features_reg = SATA_SMART_RETURN_STATUS; scmd->satacmd_device_reg = 0; /* Always device 0 */ scmd->satacmd_cmd_reg = SATAC_SMART; /* Send pkt to SATA HBA driver */ if ((*SATA_START_FUNC(sata_hba_inst))(SATA_DIP(sata_hba_inst), spkt) != SATA_TRAN_ACCEPTED || spkt->satapkt_reason != SATA_PKT_COMPLETED) { /* * Whoops, no SMART RETURN STATUS */ rval = -1; } else { if (scmd->satacmd_error_reg & SATA_ERROR_ABORT) { rval = -1; goto fail; } if (scmd->satacmd_status_reg & SATA_STATUS_ERR) { rval = -1; goto fail; } if ((scmd->satacmd_lba_mid_lsb == SMART_MAGIC_VAL_1) && (scmd->satacmd_lba_high_lsb == SMART_MAGIC_VAL_2)) rval = 0; else if ((scmd->satacmd_lba_mid_lsb == SMART_MAGIC_VAL_3) && (scmd->satacmd_lba_high_lsb == SMART_MAGIC_VAL_4)) rval = 1; else { rval = -1; goto fail; } } fail: /* Free allocated resources */ sata_pkt_free(spx); kmem_free(spx, sizeof (sata_pkt_txlate_t)); return (rval); } /* * * Returns 0 if succeeded, -1 otherwise * * Cannot be called in an interrupt context. * */ static int sata_fetch_smart_data( sata_hba_inst_t *sata_hba_inst, sata_drive_info_t *sdinfo, struct smart_data *smart_data) { sata_pkt_t *spkt; sata_cmd_t *scmd; sata_pkt_txlate_t *spx; int rval; #if ! defined(lint) ASSERT(sizeof (struct smart_data) == 512); #endif spx = kmem_zalloc(sizeof (sata_pkt_txlate_t), KM_SLEEP); spx->txlt_sata_hba_inst = sata_hba_inst; spx->txlt_scsi_pkt = NULL; /* No scsi pkt involved */ spkt = sata_pkt_alloc(spx, SLEEP_FUNC); if (spkt == NULL) { kmem_free(spx, sizeof (sata_pkt_txlate_t)); return (-1); } /* address is needed now */ spkt->satapkt_device.satadev_addr = sdinfo->satadrv_addr; /* Fill sata_pkt */ spkt->satapkt_device.satadev_addr = sdinfo->satadrv_addr; spkt->satapkt_op_mode = SATA_OPMODE_SYNCH | SATA_OPMODE_INTERRUPTS; /* Synchronous mode, no callback */ spkt->satapkt_comp = NULL; /* Timeout 30s */ spkt->satapkt_time = sata_default_pkt_time; scmd = &spkt->satapkt_cmd; scmd->satacmd_flags.sata_data_direction = SATA_DIR_READ; /* * Allocate buffer for SMART data */ scmd->satacmd_bp = sata_alloc_local_buffer(spx, sizeof (struct smart_data)); if (scmd->satacmd_bp == NULL) { sata_pkt_free(spx); kmem_free(spx, sizeof (sata_pkt_txlate_t)); SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_fetch_smart_data: " "cannot allocate buffer")); return (-1); } /* Build SMART_READ_DATA cmd in the sata_pkt */ scmd->satacmd_addr_type = 0; /* N/A */ scmd->satacmd_sec_count_lsb = 0; /* N/A */ scmd->satacmd_lba_low_lsb = 0; /* N/A */ scmd->satacmd_lba_mid_lsb = SMART_MAGIC_VAL_1; scmd->satacmd_lba_high_lsb = SMART_MAGIC_VAL_2; scmd->satacmd_features_reg = SATA_SMART_READ_DATA; scmd->satacmd_device_reg = 0; /* Always device 0 */ scmd->satacmd_cmd_reg = SATAC_SMART; /* Send pkt to SATA HBA driver */ if ((*SATA_START_FUNC(sata_hba_inst))(SATA_DIP(sata_hba_inst), spkt) != SATA_TRAN_ACCEPTED || spkt->satapkt_reason != SATA_PKT_COMPLETED) { /* * Whoops, no SMART DATA available */ rval = -1; goto fail; } else { rval = ddi_dma_sync(spx->txlt_buf_dma_handle, 0, 0, DDI_DMA_SYNC_FORKERNEL); if (rval != DDI_SUCCESS) { SATA_LOG_D((spx->txlt_sata_hba_inst, CE_WARN, "sata_fetch_smart_data: " "sync pkt failed")); rval = -1; goto fail; } bcopy(scmd->satacmd_bp->b_un.b_addr, (uint8_t *)smart_data, sizeof (struct smart_data)); } fail: /* Free allocated resources */ sata_free_local_buffer(spx); spx->txlt_sata_pkt->satapkt_cmd.satacmd_bp = NULL; sata_pkt_free(spx); kmem_free(spx, sizeof (sata_pkt_txlate_t)); return (rval); } /* * Used by LOG SENSE page 0x10 * * return 0 for success, -1 otherwise * */ static int sata_ext_smart_selftest_read_log( sata_hba_inst_t *sata_hba_inst, sata_drive_info_t *sdinfo, struct smart_ext_selftest_log *ext_selftest_log, uint16_t block_num) { sata_pkt_txlate_t *spx; sata_pkt_t *spkt; sata_cmd_t *scmd; int rval; #if ! defined(lint) ASSERT(sizeof (struct smart_ext_selftest_log) == 512); #endif spx = kmem_zalloc(sizeof (sata_pkt_txlate_t), KM_SLEEP); spx->txlt_sata_hba_inst = sata_hba_inst; spx->txlt_scsi_pkt = NULL; /* No scsi pkt involved */ spkt = sata_pkt_alloc(spx, SLEEP_FUNC); if (spkt == NULL) { kmem_free(spx, sizeof (sata_pkt_txlate_t)); return (-1); } /* address is needed now */ spkt->satapkt_device.satadev_addr = sdinfo->satadrv_addr; /* Fill sata_pkt */ spkt->satapkt_device.satadev_addr = sdinfo->satadrv_addr; spkt->satapkt_op_mode = SATA_OPMODE_SYNCH | SATA_OPMODE_INTERRUPTS; /* Synchronous mode, no callback */ spkt->satapkt_comp = NULL; /* Timeout 30s */ spkt->satapkt_time = sata_default_pkt_time; scmd = &spkt->satapkt_cmd; scmd->satacmd_flags.sata_data_direction = SATA_DIR_READ; /* * Allocate buffer for SMART extended self-test log */ scmd->satacmd_bp = sata_alloc_local_buffer(spx, sizeof (struct smart_ext_selftest_log)); if (scmd->satacmd_bp == NULL) { sata_pkt_free(spx); kmem_free(spx, sizeof (sata_pkt_txlate_t)); SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_ext_smart_selftest_log: " "cannot allocate buffer")); return (-1); } /* Build READ LOG EXT w/ extended self-test log cmd in the sata_pkt */ scmd->satacmd_addr_type = ATA_ADDR_LBA48; scmd->satacmd_sec_count_lsb = 1; /* One sector of selftest log */ scmd->satacmd_sec_count_msb = 0; /* One sector of selftest log */ scmd->satacmd_lba_low_lsb = EXT_SMART_SELFTEST_LOG_PAGE; scmd->satacmd_lba_low_msb = 0; scmd->satacmd_lba_mid_lsb = block_num & 0xff; scmd->satacmd_lba_mid_msb = block_num >> 8; scmd->satacmd_device_reg = 0; /* Always device 0 */ scmd->satacmd_cmd_reg = SATAC_READ_LOG_EXT; /* Send pkt to SATA HBA driver */ if ((*SATA_START_FUNC(sata_hba_inst))(SATA_DIP(sata_hba_inst), spkt) != SATA_TRAN_ACCEPTED || spkt->satapkt_reason != SATA_PKT_COMPLETED) { /* * Whoops, no SMART selftest log info available */ rval = -1; goto fail; } else { rval = ddi_dma_sync(spx->txlt_buf_dma_handle, 0, 0, DDI_DMA_SYNC_FORKERNEL); if (rval != DDI_SUCCESS) { SATA_LOG_D((spx->txlt_sata_hba_inst, CE_WARN, "sata_ext_smart_selftest_log: " "sync pkt failed")); rval = -1; goto fail; } bcopy(scmd->satacmd_bp->b_un.b_addr, (uint8_t *)ext_selftest_log, sizeof (struct smart_ext_selftest_log)); rval = 0; } fail: /* Free allocated resources */ sata_free_local_buffer(spx); spx->txlt_sata_pkt->satapkt_cmd.satacmd_bp = NULL; sata_pkt_free(spx); kmem_free(spx, sizeof (sata_pkt_txlate_t)); return (rval); } /* * Returns 0 for success, -1 otherwise * * SMART self-test log data is returned in buffer pointed to by selftest_log */ static int sata_smart_selftest_log( sata_hba_inst_t *sata_hba_inst, sata_drive_info_t *sdinfo, struct smart_selftest_log *selftest_log) { sata_pkt_t *spkt; sata_cmd_t *scmd; sata_pkt_txlate_t *spx; int rval; #if ! defined(lint) ASSERT(sizeof (struct smart_selftest_log) == 512); #endif spx = kmem_zalloc(sizeof (sata_pkt_txlate_t), KM_SLEEP); spx->txlt_sata_hba_inst = sata_hba_inst; spx->txlt_scsi_pkt = NULL; /* No scsi pkt involved */ spkt = sata_pkt_alloc(spx, SLEEP_FUNC); if (spkt == NULL) { kmem_free(spx, sizeof (sata_pkt_txlate_t)); return (-1); } /* address is needed now */ spkt->satapkt_device.satadev_addr = sdinfo->satadrv_addr; /* Fill sata_pkt */ spkt->satapkt_device.satadev_addr = sdinfo->satadrv_addr; spkt->satapkt_op_mode = SATA_OPMODE_SYNCH | SATA_OPMODE_INTERRUPTS; /* Synchronous mode, no callback */ spkt->satapkt_comp = NULL; /* Timeout 30s */ spkt->satapkt_time = sata_default_pkt_time; scmd = &spkt->satapkt_cmd; scmd->satacmd_flags.sata_data_direction = SATA_DIR_READ; /* * Allocate buffer for Identify Data return data */ scmd->satacmd_bp = sata_alloc_local_buffer(spx, sizeof (struct smart_selftest_log)); if (scmd->satacmd_bp == NULL) { sata_pkt_free(spx); kmem_free(spx, sizeof (sata_pkt_txlate_t)); SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_smart_selftest_log: " "cannot allocate buffer")); return (-1); } /* Build SMART_READ_DATA cmd in the sata_pkt */ scmd->satacmd_addr_type = 0; /* N/A */ scmd->satacmd_sec_count_lsb = 1; /* One sector of SMART log */ scmd->satacmd_lba_low_lsb = SMART_SELFTEST_LOG_PAGE; scmd->satacmd_lba_mid_lsb = SMART_MAGIC_VAL_1; scmd->satacmd_lba_high_lsb = SMART_MAGIC_VAL_2; scmd->satacmd_features_reg = SATA_SMART_READ_LOG; scmd->satacmd_device_reg = 0; /* Always device 0 */ scmd->satacmd_cmd_reg = SATAC_SMART; /* Send pkt to SATA HBA driver */ if ((*SATA_START_FUNC(sata_hba_inst))(SATA_DIP(sata_hba_inst), spkt) != SATA_TRAN_ACCEPTED || spkt->satapkt_reason != SATA_PKT_COMPLETED) { /* * Whoops, no SMART DATA available */ rval = -1; goto fail; } else { rval = ddi_dma_sync(spx->txlt_buf_dma_handle, 0, 0, DDI_DMA_SYNC_FORKERNEL); if (rval != DDI_SUCCESS) { SATA_LOG_D((spx->txlt_sata_hba_inst, CE_WARN, "sata_smart_selftest_log: " "sync pkt failed")); rval = -1; goto fail; } bcopy(scmd->satacmd_bp->b_un.b_addr, (uint8_t *)selftest_log, sizeof (struct smart_selftest_log)); rval = 0; } fail: /* Free allocated resources */ sata_free_local_buffer(spx); spx->txlt_sata_pkt->satapkt_cmd.satacmd_bp = NULL; sata_pkt_free(spx); kmem_free(spx, sizeof (sata_pkt_txlate_t)); return (rval); } /* * Returns 0 for success, -1 otherwise * * SMART READ LOG data is returned in buffer pointed to by smart_log */ static int sata_smart_read_log( sata_hba_inst_t *sata_hba_inst, sata_drive_info_t *sdinfo, uint8_t *smart_log, /* where the data should be returned */ uint8_t which_log, /* which log should be returned */ uint8_t log_size) /* # of 512 bytes in log */ { sata_pkt_t *spkt; sata_cmd_t *scmd; sata_pkt_txlate_t *spx; int rval; spx = kmem_zalloc(sizeof (sata_pkt_txlate_t), KM_SLEEP); spx->txlt_sata_hba_inst = sata_hba_inst; spx->txlt_scsi_pkt = NULL; /* No scsi pkt involved */ spkt = sata_pkt_alloc(spx, SLEEP_FUNC); if (spkt == NULL) { kmem_free(spx, sizeof (sata_pkt_txlate_t)); return (-1); } /* address is needed now */ spkt->satapkt_device.satadev_addr = sdinfo->satadrv_addr; /* Fill sata_pkt */ spkt->satapkt_device.satadev_addr = sdinfo->satadrv_addr; spkt->satapkt_op_mode = SATA_OPMODE_SYNCH | SATA_OPMODE_INTERRUPTS; /* Synchronous mode, no callback */ spkt->satapkt_comp = NULL; /* Timeout 30s */ spkt->satapkt_time = sata_default_pkt_time; scmd = &spkt->satapkt_cmd; scmd->satacmd_flags.sata_data_direction = SATA_DIR_READ; /* * Allocate buffer for SMART READ LOG */ scmd->satacmd_bp = sata_alloc_local_buffer(spx, log_size * 512); if (scmd->satacmd_bp == NULL) { sata_pkt_free(spx); kmem_free(spx, sizeof (sata_pkt_txlate_t)); SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_smart_read_log: " "cannot allocate buffer")); return (-1); } /* Build SMART_READ_DATA cmd in the sata_pkt */ scmd->satacmd_addr_type = 0; /* N/A */ scmd->satacmd_sec_count_lsb = log_size; /* what the caller asked for */ scmd->satacmd_lba_low_lsb = which_log; /* which log page */ scmd->satacmd_lba_mid_lsb = SMART_MAGIC_VAL_1; scmd->satacmd_lba_high_lsb = SMART_MAGIC_VAL_2; scmd->satacmd_features_reg = SATA_SMART_READ_LOG; scmd->satacmd_device_reg = 0; /* Always device 0 */ scmd->satacmd_cmd_reg = SATAC_SMART; /* Send pkt to SATA HBA driver */ if ((*SATA_START_FUNC(sata_hba_inst))(SATA_DIP(sata_hba_inst), spkt) != SATA_TRAN_ACCEPTED || spkt->satapkt_reason != SATA_PKT_COMPLETED) { /* * Whoops, no SMART DATA available */ rval = -1; goto fail; } else { rval = ddi_dma_sync(spx->txlt_buf_dma_handle, 0, 0, DDI_DMA_SYNC_FORKERNEL); if (rval != DDI_SUCCESS) { SATA_LOG_D((spx->txlt_sata_hba_inst, CE_WARN, "sata_smart_read_log: " "sync pkt failed")); rval = -1; goto fail; } bcopy(scmd->satacmd_bp->b_un.b_addr, smart_log, log_size * 512); rval = 0; } fail: /* Free allocated resources */ sata_free_local_buffer(spx); spx->txlt_sata_pkt->satapkt_cmd.satacmd_bp = NULL; sata_pkt_free(spx); kmem_free(spx, sizeof (sata_pkt_txlate_t)); return (rval); } /* * Used by LOG SENSE page 0x10 * * return 0 for success, -1 otherwise * */ static int sata_read_log_ext_directory( sata_hba_inst_t *sata_hba_inst, sata_drive_info_t *sdinfo, struct read_log_ext_directory *logdir) { sata_pkt_txlate_t *spx; sata_pkt_t *spkt; sata_cmd_t *scmd; int rval; #if ! defined(lint) ASSERT(sizeof (struct read_log_ext_directory) == 512); #endif spx = kmem_zalloc(sizeof (sata_pkt_txlate_t), KM_SLEEP); spx->txlt_sata_hba_inst = sata_hba_inst; spx->txlt_scsi_pkt = NULL; /* No scsi pkt involved */ spkt = sata_pkt_alloc(spx, SLEEP_FUNC); if (spkt == NULL) { kmem_free(spx, sizeof (sata_pkt_txlate_t)); return (-1); } /* Fill sata_pkt */ spkt->satapkt_device.satadev_addr = sdinfo->satadrv_addr; spkt->satapkt_op_mode = SATA_OPMODE_SYNCH | SATA_OPMODE_INTERRUPTS; /* Synchronous mode, no callback */ spkt->satapkt_comp = NULL; /* Timeout 30s */ spkt->satapkt_time = sata_default_pkt_time; scmd = &spkt->satapkt_cmd; scmd->satacmd_flags.sata_data_direction = SATA_DIR_READ; /* * Allocate buffer for SMART extended self-test log */ scmd->satacmd_bp = sata_alloc_local_buffer(spx, sizeof (struct read_log_ext_directory)); if (scmd->satacmd_bp == NULL) { sata_pkt_free(spx); kmem_free(spx, sizeof (sata_pkt_txlate_t)); SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_read_log_ext_directory: " "cannot allocate buffer")); return (-1); } /* Build READ LOG EXT w/ extended self-test log cmd in the sata_pkt */ scmd->satacmd_addr_type = ATA_ADDR_LBA48; scmd->satacmd_sec_count_lsb = 1; /* One sector of directory */ scmd->satacmd_sec_count_msb = 0; /* One sector of directory */ scmd->satacmd_lba_low_lsb = READ_LOG_EXT_LOG_DIRECTORY; scmd->satacmd_lba_low_msb = 0; scmd->satacmd_lba_mid_lsb = 0; scmd->satacmd_lba_mid_msb = 0; scmd->satacmd_device_reg = 0; /* Always device 0 */ scmd->satacmd_cmd_reg = SATAC_READ_LOG_EXT; /* Send pkt to SATA HBA driver */ if ((*SATA_START_FUNC(sata_hba_inst))(SATA_DIP(sata_hba_inst), spkt) != SATA_TRAN_ACCEPTED || spkt->satapkt_reason != SATA_PKT_COMPLETED) { /* * Whoops, no SMART selftest log info available */ rval = -1; goto fail; } else { rval = ddi_dma_sync(spx->txlt_buf_dma_handle, 0, 0, DDI_DMA_SYNC_FORKERNEL); if (rval != DDI_SUCCESS) { SATA_LOG_D((spx->txlt_sata_hba_inst, CE_WARN, "sata_read_log_ext_directory: " "sync pkt failed")); rval = -1; goto fail; } bcopy(scmd->satacmd_bp->b_un.b_addr, (uint8_t *)logdir, sizeof (struct read_log_ext_directory)); rval = 0; } fail: /* Free allocated resources */ sata_free_local_buffer(spx); spx->txlt_sata_pkt->satapkt_cmd.satacmd_bp = NULL; sata_pkt_free(spx); kmem_free(spx, sizeof (sata_pkt_txlate_t)); return (rval); } static void sata_gen_sysevent(sata_hba_inst_t *sata_hba_inst, sata_address_t *saddr, int hint) { char ap[MAXPATHLEN]; nvlist_t *ev_attr_list = NULL; int err; /* Allocate and build sysevent attribute list */ err = nvlist_alloc(&ev_attr_list, NV_UNIQUE_NAME_TYPE, DDI_NOSLEEP); if (err != 0) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_gen_sysevent: " "cannot allocate memory for sysevent attributes\n")); return; } /* Add hint attribute */ err = nvlist_add_string(ev_attr_list, DR_HINT, SE_HINT2STR(hint)); if (err != 0) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_gen_sysevent: " "failed to add DR_HINT attr for sysevent")); nvlist_free(ev_attr_list); return; } /* * Add AP attribute. * Get controller pathname and convert it into AP pathname by adding * a target number. */ (void) snprintf(ap, MAXPATHLEN, "/devices"); (void) ddi_pathname(SATA_DIP(sata_hba_inst), ap + strlen(ap)); (void) snprintf(ap + strlen(ap), MAXPATHLEN - strlen(ap), ":%d", SATA_MAKE_AP_NUMBER(saddr->cport, saddr->pmport, saddr->qual)); err = nvlist_add_string(ev_attr_list, DR_AP_ID, ap); if (err != 0) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_gen_sysevent: " "failed to add DR_AP_ID attr for sysevent")); nvlist_free(ev_attr_list); return; } /* Generate/log sysevent */ err = ddi_log_sysevent(SATA_DIP(sata_hba_inst), DDI_VENDOR_SUNW, EC_DR, ESC_DR_AP_STATE_CHANGE, ev_attr_list, NULL, DDI_NOSLEEP); if (err != DDI_SUCCESS) { SATA_LOG_D((sata_hba_inst, CE_WARN, "sata_gen_sysevent: " "cannot log sysevent, err code %x\n", err)); } nvlist_free(ev_attr_list); } /* * sata_xlate_errors() is used to translate (S)ATA error * information to SCSI information returned in the SCSI * packet. */ static void sata_xlate_errors(sata_pkt_txlate_t *spx) { struct scsi_pkt *scsipkt = spx->txlt_scsi_pkt; struct scsi_extended_sense *sense; scsipkt->pkt_reason = CMD_INCOMPLETE; *scsipkt->pkt_scbp = STATUS_CHECK; sense = sata_arq_sense(spx); switch (spx->txlt_sata_pkt->satapkt_reason) { case SATA_PKT_PORT_ERROR: /* * We have no device data. Assume no data transfered. */ sense->es_key = KEY_HARDWARE_ERROR; break; case SATA_PKT_DEV_ERROR: if (spx->txlt_sata_pkt->satapkt_cmd.satacmd_status_reg & SATA_STATUS_ERR) { /* * determine dev error reason from error * reg content */ sata_decode_device_error(spx, sense); break; } /* No extended sense key - no info available */ break; case SATA_PKT_TIMEOUT: /* * scsipkt->pkt_reason = CMD_TIMEOUT; This causes problems. */ scsipkt->pkt_reason = CMD_INCOMPLETE; /* No extended sense key */ break; case SATA_PKT_ABORTED: scsipkt->pkt_reason = CMD_ABORTED; /* No extended sense key */ break; case SATA_PKT_RESET: /* * pkt aborted either by an explicit reset request from * a host, or due to error recovery */ scsipkt->pkt_reason = CMD_RESET; break; default: scsipkt->pkt_reason = CMD_TRAN_ERR; break; } }