/*- * Copyright (c) 1999,2000 Michael Smith * Copyright (c) 2000 BSDi * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * Copyright (c) 2002 Eric Moore * Copyright (c) 2002 LSI Logic Corporation * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. The party using or redistributing the source code and binary forms * agrees to the disclaimer below and the terms and conditions set forth * herein. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * * $FreeBSD$ */ /* * Driver for the AMI MegaRaid family of controllers. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define AMR_DEFINE_TABLES #include #define AMR_CDEV_MAJOR 132 static d_open_t amr_open; static d_close_t amr_close; static d_ioctl_t amr_ioctl; static struct cdevsw amr_cdevsw = { .d_open = amr_open, .d_close = amr_close, .d_ioctl = amr_ioctl, .d_name = "amr", .d_maj = AMR_CDEV_MAJOR, }; /* * Initialisation, bus interface. */ static void amr_startup(void *arg); /* * Command wrappers */ static int amr_query_controller(struct amr_softc *sc); static void *amr_enquiry(struct amr_softc *sc, size_t bufsize, u_int8_t cmd, u_int8_t cmdsub, u_int8_t cmdqual); static void amr_completeio(struct amr_command *ac); static int amr_support_ext_cdb(struct amr_softc *sc); /* * Command buffer allocation. */ static void amr_alloccmd_cluster(struct amr_softc *sc); static void amr_freecmd_cluster(struct amr_command_cluster *acc); /* * Command processing. */ static int amr_bio_command(struct amr_softc *sc, struct amr_command **acp); static int amr_wait_command(struct amr_command *ac); static int amr_getslot(struct amr_command *ac); static void amr_mapcmd(struct amr_command *ac); static void amr_unmapcmd(struct amr_command *ac); static int amr_start(struct amr_command *ac); static void amr_complete(void *context, int pending); /* * Status monitoring */ static void amr_periodic(void *data); /* * Interface-specific shims */ static int amr_quartz_submit_command(struct amr_softc *sc); static int amr_quartz_get_work(struct amr_softc *sc, struct amr_mailbox *mbsave); static int amr_quartz_poll_command(struct amr_command *ac); static int amr_std_submit_command(struct amr_softc *sc); static int amr_std_get_work(struct amr_softc *sc, struct amr_mailbox *mbsave); static int amr_std_poll_command(struct amr_command *ac); static void amr_std_attach_mailbox(struct amr_softc *sc); #ifdef AMR_BOARD_INIT static int amr_quartz_init(struct amr_softc *sc); static int amr_std_init(struct amr_softc *sc); #endif /* * Debugging */ static void amr_describe_controller(struct amr_softc *sc); #ifdef AMR_DEBUG #if 0 static void amr_printcommand(struct amr_command *ac); #endif #endif /******************************************************************************** ******************************************************************************** Inline Glue ******************************************************************************** ********************************************************************************/ /******************************************************************************** ******************************************************************************** Public Interfaces ******************************************************************************** ********************************************************************************/ /******************************************************************************** * Initialise the controller and softc. */ int amr_attach(struct amr_softc *sc) { debug_called(1); /* * Initialise per-controller queues. */ TAILQ_INIT(&sc->amr_completed); TAILQ_INIT(&sc->amr_freecmds); TAILQ_INIT(&sc->amr_cmd_clusters); TAILQ_INIT(&sc->amr_ready); bioq_init(&sc->amr_bioq); #if __FreeBSD_version >= 500005 /* * Initialise command-completion task. */ TASK_INIT(&sc->amr_task_complete, 0, amr_complete, sc); #endif debug(2, "queue init done"); /* * Configure for this controller type. */ if (AMR_IS_QUARTZ(sc)) { sc->amr_submit_command = amr_quartz_submit_command; sc->amr_get_work = amr_quartz_get_work; sc->amr_poll_command = amr_quartz_poll_command; } else { sc->amr_submit_command = amr_std_submit_command; sc->amr_get_work = amr_std_get_work; sc->amr_poll_command = amr_std_poll_command; amr_std_attach_mailbox(sc);; } #ifdef AMR_BOARD_INIT if ((AMR_IS_QUARTZ(sc) ? amr_quartz_init(sc) : amr_std_init(sc)))) return(ENXIO); #endif /* * Quiz controller for features and limits. */ if (amr_query_controller(sc)) return(ENXIO); debug(2, "controller query complete"); /* * Attach our 'real' SCSI channels to CAM. */ if (amr_cam_attach(sc)) return(ENXIO); debug(2, "CAM attach done"); /* * Create the control device. */ sc->amr_dev_t = make_dev(&amr_cdevsw, device_get_unit(sc->amr_dev), UID_ROOT, GID_OPERATOR, S_IRUSR | S_IWUSR, "amr%d", device_get_unit(sc->amr_dev)); sc->amr_dev_t->si_drv1 = sc; /* * Schedule ourselves to bring the controller up once interrupts are * available. */ bzero(&sc->amr_ich, sizeof(struct intr_config_hook)); sc->amr_ich.ich_func = amr_startup; sc->amr_ich.ich_arg = sc; if (config_intrhook_establish(&sc->amr_ich) != 0) { device_printf(sc->amr_dev, "can't establish configuration hook\n"); return(ENOMEM); } /* * Print a little information about the controller. */ amr_describe_controller(sc); debug(2, "attach complete"); return(0); } /******************************************************************************** * Locate disk resources and attach children to them. */ static void amr_startup(void *arg) { struct amr_softc *sc = (struct amr_softc *)arg; struct amr_logdrive *dr; int i, error; debug_called(1); /* pull ourselves off the intrhook chain */ config_intrhook_disestablish(&sc->amr_ich); /* get up-to-date drive information */ if (amr_query_controller(sc)) { device_printf(sc->amr_dev, "can't scan controller for drives\n"); return; } /* iterate over available drives */ for (i = 0, dr = &sc->amr_drive[0]; (i < AMR_MAXLD) && (dr->al_size != 0xffffffff); i++, dr++) { /* are we already attached to this drive? */ if (dr->al_disk == 0) { /* generate geometry information */ if (dr->al_size > 0x200000) { /* extended translation? */ dr->al_heads = 255; dr->al_sectors = 63; } else { dr->al_heads = 64; dr->al_sectors = 32; } dr->al_cylinders = dr->al_size / (dr->al_heads * dr->al_sectors); dr->al_disk = device_add_child(sc->amr_dev, NULL, -1); if (dr->al_disk == 0) device_printf(sc->amr_dev, "device_add_child failed\n"); device_set_ivars(dr->al_disk, dr); } } if ((error = bus_generic_attach(sc->amr_dev)) != 0) device_printf(sc->amr_dev, "bus_generic_attach returned %d\n", error); /* mark controller back up */ sc->amr_state &= ~AMR_STATE_SHUTDOWN; /* interrupts will be enabled before we do anything more */ sc->amr_state |= AMR_STATE_INTEN; /* * Start the timeout routine. */ /* sc->amr_timeout = timeout(amr_periodic, sc, hz);*/ return; } /******************************************************************************* * Free resources associated with a controller instance */ void amr_free(struct amr_softc *sc) { struct amr_command_cluster *acc; /* detach from CAM */ amr_cam_detach(sc); /* cancel status timeout */ untimeout(amr_periodic, sc, sc->amr_timeout); /* throw away any command buffers */ while ((acc = TAILQ_FIRST(&sc->amr_cmd_clusters)) != NULL) { TAILQ_REMOVE(&sc->amr_cmd_clusters, acc, acc_link); amr_freecmd_cluster(acc); } /* destroy control device */ if( sc->amr_dev_t != (dev_t)NULL) destroy_dev(sc->amr_dev_t); } /******************************************************************************* * Receive a bio structure from a child device and queue it on a particular * disk resource, then poke the disk resource to start as much work as it can. */ int amr_submit_bio(struct amr_softc *sc, struct bio *bio) { debug_called(2); amr_enqueue_bio(sc, bio); amr_startio(sc); return(0); } /******************************************************************************** * Accept an open operation on the control device. */ static int amr_open(dev_t dev, int flags, int fmt, d_thread_t *td) { int unit = minor(dev); struct amr_softc *sc = devclass_get_softc(devclass_find("amr"), unit); debug_called(1); sc->amr_state |= AMR_STATE_OPEN; return(0); } /******************************************************************************** * Accept the last close on the control device. */ static int amr_close(dev_t dev, int flags, int fmt, d_thread_t *td) { int unit = minor(dev); struct amr_softc *sc = devclass_get_softc(devclass_find("amr"), unit); debug_called(1); sc->amr_state &= ~AMR_STATE_OPEN; return (0); } /******************************************************************************** * Handle controller-specific control operations. */ static int amr_ioctl(dev_t dev, u_long cmd, caddr_t addr, int32_t flag, d_thread_t *td) { struct amr_softc *sc = (struct amr_softc *)dev->si_drv1; int *arg = (int *)addr; struct amr_user_ioctl *au = (struct amr_user_ioctl *)addr; struct amr_command *ac; struct amr_mailbox_ioctl *mbi; struct amr_passthrough *ap; void *dp; int error; debug_called(1); error = 0; dp = NULL; ap = NULL; ac = NULL; switch(cmd) { case AMR_IO_VERSION: debug(1, "AMR_IO_VERSION"); *arg = AMR_IO_VERSION_NUMBER; break; case AMR_IO_COMMAND: debug(1, "AMR_IO_COMMAND 0x%x", au->au_cmd[0]); /* handle inbound data buffer */ if (au->au_length != 0) { if ((dp = malloc(au->au_length, M_DEVBUF, M_WAITOK)) == NULL) { error = ENOMEM; break; } if ((error = copyin(au->au_buffer, dp, au->au_length)) != 0) break; debug(2, "copyin %ld bytes from %p -> %p", au->au_length, au->au_buffer, dp); } if ((ac = amr_alloccmd(sc)) == NULL) { error = ENOMEM; break; } /* handle SCSI passthrough command */ if (au->au_cmd[0] == AMR_CMD_PASS) { if ((ap = malloc(sizeof(*ap), M_DEVBUF, M_WAITOK | M_ZERO)) == NULL) { error = ENOMEM; break; } /* copy cdb */ ap->ap_cdb_length = au->au_cmd[2]; bcopy(&au->au_cmd[3], &ap->ap_cdb[0], ap->ap_cdb_length); /* build passthrough */ ap->ap_timeout = au->au_cmd[ap->ap_cdb_length + 3] & 0x07; ap->ap_ars = (au->au_cmd[ap->ap_cdb_length + 3] & 0x08) ? 1 : 0; ap->ap_islogical = (au->au_cmd[ap->ap_cdb_length + 3] & 0x80) ? 1 : 0; ap->ap_logical_drive_no = au->au_cmd[ap->ap_cdb_length + 4]; ap->ap_channel = au->au_cmd[ap->ap_cdb_length + 5]; ap->ap_scsi_id = au->au_cmd[ap->ap_cdb_length + 6]; ap->ap_request_sense_length = 14; ap->ap_data_transfer_length = au->au_length; /* XXX what about the request-sense area? does the caller want it? */ /* build command */ ac->ac_data = ap; ac->ac_length = sizeof(*ap); ac->ac_flags |= AMR_CMD_DATAOUT; ac->ac_ccb_data = dp; ac->ac_ccb_length = au->au_length; if (au->au_direction & AMR_IO_READ) ac->ac_flags |= AMR_CMD_CCB_DATAIN; if (au->au_direction & AMR_IO_WRITE) ac->ac_flags |= AMR_CMD_CCB_DATAOUT; ac->ac_mailbox.mb_command = AMR_CMD_PASS; } else { /* direct command to controller */ mbi = (struct amr_mailbox_ioctl *)&ac->ac_mailbox; /* copy pertinent mailbox items */ mbi->mb_command = au->au_cmd[0]; mbi->mb_channel = au->au_cmd[1]; mbi->mb_param = au->au_cmd[2]; mbi->mb_pad[0] = au->au_cmd[3]; mbi->mb_drive = au->au_cmd[4]; /* build the command */ ac->ac_data = dp; ac->ac_length = au->au_length; if (au->au_direction & AMR_IO_READ) ac->ac_flags |= AMR_CMD_DATAIN; if (au->au_direction & AMR_IO_WRITE) ac->ac_flags |= AMR_CMD_DATAOUT; } /* run the command */ if ((error = amr_wait_command(ac)) != 0) break; /* copy out data and set status */ if (au->au_length != 0) error = copyout(dp, au->au_buffer, au->au_length); debug(2, "copyout %ld bytes from %p -> %p", au->au_length, dp, au->au_buffer); if (dp != NULL) debug(2, "%16d", (int)dp); au->au_status = ac->ac_status; break; default: debug(1, "unknown ioctl 0x%lx", cmd); error = ENOIOCTL; break; } if (dp != NULL) free(dp, M_DEVBUF); if (ap != NULL) free(ap, M_DEVBUF); if (ac != NULL) amr_releasecmd(ac); return(error); } /******************************************************************************** ******************************************************************************** Status Monitoring ******************************************************************************** ********************************************************************************/ /******************************************************************************** * Perform a periodic check of the controller status */ static void amr_periodic(void *data) { struct amr_softc *sc = (struct amr_softc *)data; debug_called(2); /* XXX perform periodic status checks here */ /* compensate for missed interrupts */ amr_done(sc); /* reschedule */ sc->amr_timeout = timeout(amr_periodic, sc, hz); } /******************************************************************************** ******************************************************************************** Command Wrappers ******************************************************************************** ********************************************************************************/ /******************************************************************************** * Interrogate the controller for the operational parameters we require. */ static int amr_query_controller(struct amr_softc *sc) { struct amr_enquiry3 *aex; struct amr_prodinfo *ap; struct amr_enquiry *ae; int ldrv; /* * If we haven't found the real limit yet, let us have a couple of commands in * order to be able to probe. */ if (sc->amr_maxio == 0) sc->amr_maxio = 2; /* * Greater than 10 byte cdb support */ sc->support_ext_cdb = amr_support_ext_cdb(sc); if(sc->support_ext_cdb) { debug(2,"supports extended CDBs."); } /* * Try to issue an ENQUIRY3 command */ if ((aex = amr_enquiry(sc, 2048, AMR_CMD_CONFIG, AMR_CONFIG_ENQ3, AMR_CONFIG_ENQ3_SOLICITED_FULL)) != NULL) { /* * Fetch current state of logical drives. */ for (ldrv = 0; ldrv < aex->ae_numldrives; ldrv++) { sc->amr_drive[ldrv].al_size = aex->ae_drivesize[ldrv]; sc->amr_drive[ldrv].al_state = aex->ae_drivestate[ldrv]; sc->amr_drive[ldrv].al_properties = aex->ae_driveprop[ldrv]; debug(2, " drive %d: %d state %x properties %x\n", ldrv, sc->amr_drive[ldrv].al_size, sc->amr_drive[ldrv].al_state, sc->amr_drive[ldrv].al_properties); } free(aex, M_DEVBUF); /* * Get product info for channel count. */ if ((ap = amr_enquiry(sc, 2048, AMR_CMD_CONFIG, AMR_CONFIG_PRODUCT_INFO, 0)) == NULL) { device_printf(sc->amr_dev, "can't obtain product data from controller\n"); return(1); } sc->amr_maxdrives = 40; sc->amr_maxchan = ap->ap_nschan; sc->amr_maxio = ap->ap_maxio; sc->amr_type |= AMR_TYPE_40LD; free(ap, M_DEVBUF); } else { /* failed, try the 8LD ENQUIRY commands */ if ((ae = (struct amr_enquiry *)amr_enquiry(sc, 2048, AMR_CMD_EXT_ENQUIRY2, 0, 0)) == NULL) { if ((ae = (struct amr_enquiry *)amr_enquiry(sc, 2048, AMR_CMD_ENQUIRY, 0, 0)) == NULL) { device_printf(sc->amr_dev, "can't obtain configuration data from controller\n"); return(1); } ae->ae_signature = 0; } /* * Fetch current state of logical drives. */ for (ldrv = 0; ldrv < ae->ae_ldrv.al_numdrives; ldrv++) { sc->amr_drive[ldrv].al_size = ae->ae_ldrv.al_size[ldrv]; sc->amr_drive[ldrv].al_state = ae->ae_ldrv.al_state[ldrv]; sc->amr_drive[ldrv].al_properties = ae->ae_ldrv.al_properties[ldrv]; debug(2, " drive %d: %d state %x properties %x\n", ldrv, sc->amr_drive[ldrv].al_size, sc->amr_drive[ldrv].al_state, sc->amr_drive[ldrv].al_properties); } sc->amr_maxdrives = 8; sc->amr_maxchan = ae->ae_adapter.aa_channels; sc->amr_maxio = ae->ae_adapter.aa_maxio; free(ae, M_DEVBUF); } /* * Mark remaining drives as unused. */ for (; ldrv < AMR_MAXLD; ldrv++) sc->amr_drive[ldrv].al_size = 0xffffffff; /* * Cap the maximum number of outstanding I/Os. AMI's Linux driver doesn't trust * the controller's reported value, and lockups have been seen when we do. */ sc->amr_maxio = imin(sc->amr_maxio, AMR_LIMITCMD); return(0); } /******************************************************************************** * Run a generic enquiry-style command. */ static void * amr_enquiry(struct amr_softc *sc, size_t bufsize, u_int8_t cmd, u_int8_t cmdsub, u_int8_t cmdqual) { struct amr_command *ac; void *result; u_int8_t *mbox; int error; debug_called(1); error = 1; result = NULL; /* get ourselves a command buffer */ if ((ac = amr_alloccmd(sc)) == NULL) goto out; /* allocate the response structure */ if ((result = malloc(bufsize, M_DEVBUF, M_NOWAIT)) == NULL) goto out; /* set command flags */ ac->ac_flags |= AMR_CMD_PRIORITY | AMR_CMD_DATAOUT; /* point the command at our data */ ac->ac_data = result; ac->ac_length = bufsize; /* build the command proper */ mbox = (u_int8_t *)&ac->ac_mailbox; /* XXX want a real structure for this? */ mbox[0] = cmd; mbox[2] = cmdsub; mbox[3] = cmdqual; /* can't assume that interrupts are going to work here, so play it safe */ if (sc->amr_poll_command(ac)) goto out; error = ac->ac_status; out: if (ac != NULL) amr_releasecmd(ac); if ((error != 0) && (result != NULL)) { free(result, M_DEVBUF); result = NULL; } return(result); } /******************************************************************************** * Flush the controller's internal cache, return status. */ int amr_flush(struct amr_softc *sc) { struct amr_command *ac; int error; /* get ourselves a command buffer */ error = 1; if ((ac = amr_alloccmd(sc)) == NULL) goto out; /* set command flags */ ac->ac_flags |= AMR_CMD_PRIORITY | AMR_CMD_DATAOUT; /* build the command proper */ ac->ac_mailbox.mb_command = AMR_CMD_FLUSH; /* we have to poll, as the system may be going down or otherwise damaged */ if (sc->amr_poll_command(ac)) goto out; error = ac->ac_status; out: if (ac != NULL) amr_releasecmd(ac); return(error); } /******************************************************************************** * Detect extented cdb >> greater than 10 byte cdb support * returns '1' means this support exist * returns '0' means this support doesn't exist */ static int amr_support_ext_cdb(struct amr_softc *sc) { struct amr_command *ac; u_int8_t *mbox; int error; /* get ourselves a command buffer */ error = 0; if ((ac = amr_alloccmd(sc)) == NULL) goto out; /* set command flags */ ac->ac_flags |= AMR_CMD_PRIORITY | AMR_CMD_DATAOUT; /* build the command proper */ mbox = (u_int8_t *)&ac->ac_mailbox; /* XXX want a real structure for this? */ mbox[0] = 0xA4; mbox[2] = 0x16; /* we have to poll, as the system may be going down or otherwise damaged */ if (sc->amr_poll_command(ac)) goto out; if( ac->ac_status == AMR_STATUS_SUCCESS ) { error = 1; } out: if (ac != NULL) amr_releasecmd(ac); return(error); } /******************************************************************************** * Try to find I/O work for the controller from one or more of the work queues. * * We make the assumption that if the controller is not ready to take a command * at some given time, it will generate an interrupt at some later time when * it is. */ void amr_startio(struct amr_softc *sc) { struct amr_command *ac; /* spin until something prevents us from doing any work */ for (;;) { /* try to get a ready command */ ac = amr_dequeue_ready(sc); /* if that failed, build a command from a bio */ if (ac == NULL) (void)amr_bio_command(sc, &ac); /* if that failed, build a command from a ccb */ if (ac == NULL) (void)amr_cam_command(sc, &ac); /* if we don't have anything to do, give up */ if (ac == NULL) break; /* try to give the command to the controller; if this fails save it for later and give up */ if (amr_start(ac)) { debug(2, "controller busy, command deferred"); amr_requeue_ready(ac); /* XXX schedule retry very soon? */ break; } } } /******************************************************************************** * Handle completion of an I/O command. */ static void amr_completeio(struct amr_command *ac) { struct amr_softc *sc = ac->ac_sc; if (ac->ac_status != AMR_STATUS_SUCCESS) { /* could be more verbose here? */ ac->ac_bio->bio_error = EIO; ac->ac_bio->bio_flags |= BIO_ERROR; device_printf(sc->amr_dev, "I/O error - 0x%x\n", ac->ac_status); /* amr_printcommand(ac);*/ } amrd_intr(ac->ac_bio); amr_releasecmd(ac); } /******************************************************************************** ******************************************************************************** Command Processing ******************************************************************************** ********************************************************************************/ /******************************************************************************** * Convert a bio off the top of the bio queue into a command. */ static int amr_bio_command(struct amr_softc *sc, struct amr_command **acp) { struct amr_command *ac; struct amrd_softc *amrd; struct bio *bio; int error; int blkcount; int driveno; int cmd; ac = NULL; error = 0; /* get a bio to work on */ if ((bio = amr_dequeue_bio(sc)) == NULL) goto out; /* get a command */ if ((ac = amr_alloccmd(sc)) == NULL) { error = ENOMEM; goto out; } /* connect the bio to the command */ ac->ac_complete = amr_completeio; ac->ac_bio = bio; ac->ac_data = bio->bio_data; ac->ac_length = bio->bio_bcount; if (BIO_IS_READ(bio)) { ac->ac_flags |= AMR_CMD_DATAIN; cmd = AMR_CMD_LREAD; } else { ac->ac_flags |= AMR_CMD_DATAOUT; cmd = AMR_CMD_LWRITE; } amrd = (struct amrd_softc *)bio->bio_disk->d_drv1; driveno = amrd->amrd_drive - sc->amr_drive; blkcount = (bio->bio_bcount + AMR_BLKSIZE - 1) / AMR_BLKSIZE; ac->ac_mailbox.mb_command = cmd; ac->ac_mailbox.mb_blkcount = blkcount; ac->ac_mailbox.mb_lba = bio->bio_pblkno; ac->ac_mailbox.mb_drive = driveno; /* we fill in the s/g related data when the command is mapped */ if ((bio->bio_pblkno + blkcount) > sc->amr_drive[driveno].al_size) device_printf(sc->amr_dev, "I/O beyond end of unit (%lld,%d > %lu)\n", (long long)bio->bio_pblkno, blkcount, (u_long)sc->amr_drive[driveno].al_size); out: if (error != 0) { if (ac != NULL) amr_releasecmd(ac); if (bio != NULL) /* this breaks ordering... */ amr_enqueue_bio(sc, bio); } *acp = ac; return(error); } /******************************************************************************** * Take a command, submit it to the controller and sleep until it completes * or fails. Interrupts must be enabled, returns nonzero on error. */ static int amr_wait_command(struct amr_command *ac) { int error, count; debug_called(1); ac->ac_complete = NULL; ac->ac_flags |= AMR_CMD_SLEEP; if ((error = amr_start(ac)) != 0) return(error); count = 0; /* XXX better timeout? */ while ((ac->ac_flags & AMR_CMD_BUSY) && (count < 30)) { tsleep(ac, PRIBIO | PCATCH, "amrwcmd", hz); } return(0); } /******************************************************************************** * Take a command, submit it to the controller and busy-wait for it to return. * Returns nonzero on error. Can be safely called with interrupts enabled. */ static int amr_std_poll_command(struct amr_command *ac) { struct amr_softc *sc = ac->ac_sc; int error, count; debug_called(2); ac->ac_complete = NULL; if ((error = amr_start(ac)) != 0) return(error); count = 0; do { /* * Poll for completion, although the interrupt handler may beat us to it. * Note that the timeout here is somewhat arbitrary. */ amr_done(sc); DELAY(1000); } while ((ac->ac_flags & AMR_CMD_BUSY) && (count++ < 1000)); if (!(ac->ac_flags & AMR_CMD_BUSY)) { error = 0; } else { /* XXX the slot is now marked permanently busy */ error = EIO; device_printf(sc->amr_dev, "polled command timeout\n"); } return(error); } /******************************************************************************** * Take a command, submit it to the controller and busy-wait for it to return. * Returns nonzero on error. Can be safely called with interrupts enabled. */ static int amr_quartz_poll_command(struct amr_command *ac) { struct amr_softc *sc = ac->ac_sc; int s; int error,count; debug_called(2); /* now we have a slot, we can map the command (unmapped in amr_complete) */ amr_mapcmd(ac); s = splbio(); count=0; while (sc->amr_busyslots){ tsleep(sc, PRIBIO | PCATCH, "amrpoll", hz); if(count++>10) { break; } } if(sc->amr_busyslots) { device_printf(sc->amr_dev, "adapter is busy\n"); splx(s); amr_unmapcmd(ac); ac->ac_status=0; return(1); } bcopy(&ac->ac_mailbox, (void *)(uintptr_t)(volatile void *)sc->amr_mailbox, AMR_MBOX_CMDSIZE); /* clear the poll/ack fields in the mailbox */ sc->amr_mailbox->mb_ident = 0xFE; sc->amr_mailbox->mb_nstatus = 0xFF; sc->amr_mailbox->mb_status = 0xFF; sc->amr_mailbox->mb_poll = 0; sc->amr_mailbox->mb_ack = 0; sc->amr_mailbox->mb_busy = 1; AMR_QPUT_IDB(sc, sc->amr_mailboxphys | AMR_QIDB_SUBMIT); while(sc->amr_mailbox->mb_nstatus == 0xFF); while(sc->amr_mailbox->mb_status == 0xFF); ac->ac_status=sc->amr_mailbox->mb_status; error = (ac->ac_status !=AMR_STATUS_SUCCESS) ? 1:0; while(sc->amr_mailbox->mb_poll != 0x77); sc->amr_mailbox->mb_poll = 0; sc->amr_mailbox->mb_ack = 0x77; /* acknowledge that we have the commands */ AMR_QPUT_IDB(sc, sc->amr_mailboxphys | AMR_QIDB_ACK); while(AMR_QGET_IDB(sc) & AMR_QIDB_ACK); splx(s); /* unmap the command's data buffer */ amr_unmapcmd(ac); return(error); } /******************************************************************************** * Get a free command slot for a command if it doesn't already have one. * * May be safely called multiple times for a given command. */ static int amr_getslot(struct amr_command *ac) { struct amr_softc *sc = ac->ac_sc; int s, slot, limit, error; debug_called(3); /* if the command already has a slot, don't try to give it another one */ if (ac->ac_slot != 0) return(0); /* enforce slot usage limit */ limit = (ac->ac_flags & AMR_CMD_PRIORITY) ? sc->amr_maxio : sc->amr_maxio - 4; if (sc->amr_busyslots > limit) return(EBUSY); /* * Allocate a slot. XXX linear scan is slow */ error = EBUSY; s = splbio(); for (slot = 0; slot < sc->amr_maxio; slot++) { if (sc->amr_busycmd[slot] == NULL) { sc->amr_busycmd[slot] = ac; sc->amr_busyslots++; ac->ac_slot = slot; error = 0; break; } } splx(s); return(error); } /******************************************************************************** * Map/unmap (ac)'s data in the controller's addressable space as required. * * These functions may be safely called multiple times on a given command. */ static void amr_setup_dmamap(void *arg, bus_dma_segment_t *segs, int nsegments, int error) { struct amr_command *ac = (struct amr_command *)arg; struct amr_softc *sc = ac->ac_sc; struct amr_sgentry *sg; int i; u_int8_t *sgc; debug_called(3); /* get base address of s/g table */ sg = sc->amr_sgtable + (ac->ac_slot * AMR_NSEG); /* save data physical address */ ac->ac_dataphys = segs[0].ds_addr; /* for AMR_CMD_CONFIG the s/g count goes elsewhere */ if (ac->ac_mailbox.mb_command == AMR_CMD_CONFIG) { sgc = &(((struct amr_mailbox_ioctl *)&ac->ac_mailbox)->mb_param); } else { sgc = &ac->ac_mailbox.mb_nsgelem; } /* decide whether we need to populate the s/g table */ if (nsegments < 2) { *sgc = 0; ac->ac_mailbox.mb_nsgelem = 0; ac->ac_mailbox.mb_physaddr = ac->ac_dataphys; } else { ac->ac_mailbox.mb_nsgelem = nsegments; *sgc = nsegments; ac->ac_mailbox.mb_physaddr = sc->amr_sgbusaddr + (ac->ac_slot * AMR_NSEG * sizeof(struct amr_sgentry)); for (i = 0; i < nsegments; i++, sg++) { sg->sg_addr = segs[i].ds_addr; sg->sg_count = segs[i].ds_len; } } } static void amr_setup_ccbmap(void *arg, bus_dma_segment_t *segs, int nsegments, int error) { struct amr_command *ac = (struct amr_command *)arg; struct amr_softc *sc = ac->ac_sc; struct amr_sgentry *sg; struct amr_passthrough *ap = (struct amr_passthrough *)ac->ac_data; struct amr_ext_passthrough *aep = (struct amr_ext_passthrough *)ac->ac_data; int i; /* get base address of s/g table */ sg = sc->amr_sgtable + (ac->ac_slot * AMR_NSEG); /* decide whether we need to populate the s/g table */ if( ac->ac_mailbox.mb_command == AMR_CMD_EXTPASS ) { if (nsegments < 2) { aep->ap_no_sg_elements = 0; aep->ap_data_transfer_address = segs[0].ds_addr; } else { /* save s/g table information in passthrough */ aep->ap_no_sg_elements = nsegments; aep->ap_data_transfer_address = sc->amr_sgbusaddr + (ac->ac_slot * AMR_NSEG * sizeof(struct amr_sgentry)); /* populate s/g table (overwrites previous call which mapped the passthrough) */ for (i = 0; i < nsegments; i++, sg++) { sg->sg_addr = segs[i].ds_addr; sg->sg_count = segs[i].ds_len; debug(3, " %d: 0x%x/%d", i, sg->sg_addr, sg->sg_count); } } debug(3, "slot %d %d segments at 0x%x, passthrough at 0x%x", ac->ac_slot, aep->ap_no_sg_elements, aep->ap_data_transfer_address, ac->ac_dataphys); } else { if (nsegments < 2) { ap->ap_no_sg_elements = 0; ap->ap_data_transfer_address = segs[0].ds_addr; } else { /* save s/g table information in passthrough */ ap->ap_no_sg_elements = nsegments; ap->ap_data_transfer_address = sc->amr_sgbusaddr + (ac->ac_slot * AMR_NSEG * sizeof(struct amr_sgentry)); /* populate s/g table (overwrites previous call which mapped the passthrough) */ for (i = 0; i < nsegments; i++, sg++) { sg->sg_addr = segs[i].ds_addr; sg->sg_count = segs[i].ds_len; debug(3, " %d: 0x%x/%d", i, sg->sg_addr, sg->sg_count); } } debug(3, "slot %d %d segments at 0x%x, passthrough at 0x%x", ac->ac_slot, ap->ap_no_sg_elements, ap->ap_data_transfer_address, ac->ac_dataphys); } } static void amr_mapcmd(struct amr_command *ac) { struct amr_softc *sc = ac->ac_sc; debug_called(3); /* if the command involves data at all, and hasn't been mapped */ if (!(ac->ac_flags & AMR_CMD_MAPPED)) { if (ac->ac_data != NULL) { /* map the data buffers into bus space and build the s/g list */ bus_dmamap_load(sc->amr_buffer_dmat, ac->ac_dmamap, ac->ac_data, ac->ac_length, amr_setup_dmamap, ac, 0); if (ac->ac_flags & AMR_CMD_DATAIN) bus_dmamap_sync(sc->amr_buffer_dmat, ac->ac_dmamap, BUS_DMASYNC_PREREAD); if (ac->ac_flags & AMR_CMD_DATAOUT) bus_dmamap_sync(sc->amr_buffer_dmat, ac->ac_dmamap, BUS_DMASYNC_PREWRITE); } if (ac->ac_ccb_data != NULL) { bus_dmamap_load(sc->amr_buffer_dmat, ac->ac_ccb_dmamap, ac->ac_ccb_data, ac->ac_ccb_length, amr_setup_ccbmap, ac, 0); if (ac->ac_flags & AMR_CMD_CCB_DATAIN) bus_dmamap_sync(sc->amr_buffer_dmat, ac->ac_ccb_dmamap, BUS_DMASYNC_PREREAD); if (ac->ac_flags & AMR_CMD_CCB_DATAOUT) bus_dmamap_sync(sc->amr_buffer_dmat, ac->ac_ccb_dmamap, BUS_DMASYNC_PREWRITE); } ac->ac_flags |= AMR_CMD_MAPPED; } } static void amr_unmapcmd(struct amr_command *ac) { struct amr_softc *sc = ac->ac_sc; debug_called(3); /* if the command involved data at all and was mapped */ if (ac->ac_flags & AMR_CMD_MAPPED) { if (ac->ac_data != NULL) { if (ac->ac_flags & AMR_CMD_DATAIN) bus_dmamap_sync(sc->amr_buffer_dmat, ac->ac_dmamap, BUS_DMASYNC_POSTREAD); if (ac->ac_flags & AMR_CMD_DATAOUT) bus_dmamap_sync(sc->amr_buffer_dmat, ac->ac_dmamap, BUS_DMASYNC_POSTWRITE); bus_dmamap_unload(sc->amr_buffer_dmat, ac->ac_dmamap); } if (ac->ac_ccb_data != NULL) { if (ac->ac_flags & AMR_CMD_CCB_DATAIN) bus_dmamap_sync(sc->amr_buffer_dmat, ac->ac_ccb_dmamap, BUS_DMASYNC_POSTREAD); if (ac->ac_flags & AMR_CMD_CCB_DATAOUT) bus_dmamap_sync(sc->amr_buffer_dmat, ac->ac_ccb_dmamap, BUS_DMASYNC_POSTWRITE); bus_dmamap_unload(sc->amr_buffer_dmat, ac->ac_ccb_dmamap); } ac->ac_flags &= ~AMR_CMD_MAPPED; } } /******************************************************************************** * Take a command and give it to the controller, returns 0 if successful, or * EBUSY if the command should be retried later. */ static int amr_start(struct amr_command *ac) { struct amr_softc *sc = ac->ac_sc; int done, s, i; debug_called(3); /* mark command as busy so that polling consumer can tell */ ac->ac_flags |= AMR_CMD_BUSY; /* get a command slot (freed in amr_done) */ if (amr_getslot(ac)) return(EBUSY); /* now we have a slot, we can map the command (unmapped in amr_complete) */ amr_mapcmd(ac); /* mark the new mailbox we are going to copy in as busy */ ac->ac_mailbox.mb_busy = 1; /* clear the poll/ack fields in the mailbox */ sc->amr_mailbox->mb_poll = 0; sc->amr_mailbox->mb_ack = 0; /* * Save the slot number so that we can locate this command when complete. * Note that ident = 0 seems to be special, so we don't use it. */ ac->ac_mailbox.mb_ident = ac->ac_slot + 1; /* * Spin waiting for the mailbox, give up after ~1 second. We expect the * controller to be able to handle our I/O. * * XXX perhaps we should wait for less time, and count on the deferred command * handling to deal with retries? */ debug(4, "wait for mailbox"); for (i = 10000, done = 0; (i > 0) && !done; i--) { s = splbio(); /* is the mailbox free? */ if (sc->amr_mailbox->mb_busy == 0) { debug(4, "got mailbox"); sc->amr_mailbox64->mb64_segment = 0; bcopy(&ac->ac_mailbox, (void *)(uintptr_t)(volatile void *)sc->amr_mailbox, AMR_MBOX_CMDSIZE); done = 1; /* not free, spin waiting */ } else { debug(4, "busy flag %x\n", sc->amr_mailbox->mb_busy); /* this is somewhat ugly */ DELAY(100); } splx(s); /* drop spl to allow completion interrupts */ } /* * Now give the command to the controller */ if (done) { if (sc->amr_submit_command(sc)) { /* the controller wasn't ready to take the command, forget that we tried to post it */ sc->amr_mailbox->mb_busy = 0; return(EBUSY); } debug(3, "posted command"); return(0); } /* * The controller wouldn't take the command. Return the command as busy * so that it is retried later. */ return(EBUSY); } /******************************************************************************** * Extract one or more completed commands from the controller (sc) * * Returns nonzero if any commands on the work queue were marked as completed. */ int amr_done(struct amr_softc *sc) { struct amr_command *ac; struct amr_mailbox mbox; int i, idx, result; debug_called(3); /* See if there's anything for us to do */ result = 0; /* loop collecting completed commands */ for (;;) { /* poll for a completed command's identifier and status */ if (sc->amr_get_work(sc, &mbox)) { result = 1; /* iterate over completed commands in this result */ for (i = 0; i < mbox.mb_nstatus; i++) { /* get pointer to busy command */ idx = mbox.mb_completed[i] - 1; ac = sc->amr_busycmd[idx]; /* really a busy command? */ if (ac != NULL) { /* pull the command from the busy index */ sc->amr_busycmd[idx] = NULL; sc->amr_busyslots--; /* save status for later use */ ac->ac_status = mbox.mb_status; amr_enqueue_completed(ac); debug(3, "completed command with status %x", mbox.mb_status); } else { device_printf(sc->amr_dev, "bad slot %d completed\n", idx); } } } else { break; /* no work */ } } /* if we've completed any commands, try posting some more */ if (result) amr_startio(sc); /* handle completion and timeouts */ #if __FreeBSD_version >= 500005 if (sc->amr_state & AMR_STATE_INTEN) taskqueue_enqueue(taskqueue_swi_giant, &sc->amr_task_complete); else #endif amr_complete(sc, 0); return(result); } /******************************************************************************** * Do completion processing on done commands on (sc) */ static void amr_complete(void *context, int pending) { struct amr_softc *sc = (struct amr_softc *)context; struct amr_command *ac; debug_called(3); /* pull completed commands off the queue */ for (;;) { ac = amr_dequeue_completed(sc); if (ac == NULL) break; /* unmap the command's data buffer */ amr_unmapcmd(ac); /* unbusy the command */ ac->ac_flags &= ~AMR_CMD_BUSY; /* * Is there a completion handler? */ if (ac->ac_complete != NULL) { ac->ac_complete(ac); /* * Is someone sleeping on this one? */ } else if (ac->ac_flags & AMR_CMD_SLEEP) { wakeup(ac); } if(!sc->amr_busyslots) { wakeup(sc); } } } /******************************************************************************** ******************************************************************************** Command Buffer Management ******************************************************************************** ********************************************************************************/ /******************************************************************************** * Get a new command buffer. * * This may return NULL in low-memory cases. * * If possible, we recycle a command buffer that's been used before. */ struct amr_command * amr_alloccmd(struct amr_softc *sc) { struct amr_command *ac; debug_called(3); ac = amr_dequeue_free(sc); if (ac == NULL) { amr_alloccmd_cluster(sc); ac = amr_dequeue_free(sc); } if (ac == NULL) return(NULL); /* clear out significant fields */ ac->ac_slot = 0; ac->ac_status = 0; bzero(&ac->ac_mailbox, sizeof(struct amr_mailbox)); ac->ac_flags = 0; ac->ac_bio = NULL; ac->ac_data = NULL; ac->ac_ccb_data = NULL; ac->ac_complete = NULL; return(ac); } /******************************************************************************** * Release a command buffer for recycling. */ void amr_releasecmd(struct amr_command *ac) { debug_called(3); amr_enqueue_free(ac); } /******************************************************************************** * Allocate a new command cluster and initialise it. */ static void amr_alloccmd_cluster(struct amr_softc *sc) { struct amr_command_cluster *acc; struct amr_command *ac; int s, i; acc = malloc(AMR_CMD_CLUSTERSIZE, M_DEVBUF, M_NOWAIT); if (acc != NULL) { s = splbio(); TAILQ_INSERT_TAIL(&sc->amr_cmd_clusters, acc, acc_link); splx(s); for (i = 0; i < AMR_CMD_CLUSTERCOUNT; i++) { ac = &acc->acc_command[i]; bzero(ac, sizeof(*ac)); ac->ac_sc = sc; if (!bus_dmamap_create(sc->amr_buffer_dmat, 0, &ac->ac_dmamap) && !bus_dmamap_create(sc->amr_buffer_dmat, 0, &ac->ac_ccb_dmamap)) amr_releasecmd(ac); } } } /******************************************************************************** * Free a command cluster */ static void amr_freecmd_cluster(struct amr_command_cluster *acc) { struct amr_softc *sc = acc->acc_command[0].ac_sc; int i; for (i = 0; i < AMR_CMD_CLUSTERCOUNT; i++) bus_dmamap_destroy(sc->amr_buffer_dmat, acc->acc_command[i].ac_dmamap); free(acc, M_DEVBUF); } /******************************************************************************** ******************************************************************************** Interface-specific Shims ******************************************************************************** ********************************************************************************/ /******************************************************************************** * Tell the controller that the mailbox contains a valid command */ static int amr_quartz_submit_command(struct amr_softc *sc) { debug_called(3); if (AMR_QGET_IDB(sc) & AMR_QIDB_SUBMIT) return(EBUSY); AMR_QPUT_IDB(sc, sc->amr_mailboxphys | AMR_QIDB_SUBMIT); return(0); } static int amr_std_submit_command(struct amr_softc *sc) { debug_called(3); if (AMR_SGET_MBSTAT(sc) & AMR_SMBOX_BUSYFLAG) return(EBUSY); AMR_SPOST_COMMAND(sc); return(0); } /******************************************************************************** * Claim any work that the controller has completed; acknowledge completion, * save details of the completion in (mbsave) */ static int amr_quartz_get_work(struct amr_softc *sc, struct amr_mailbox *mbsave) { int s, worked; u_int32_t outd; debug_called(3); worked = 0; s = splbio(); /* work waiting for us? */ if ((outd = AMR_QGET_ODB(sc)) == AMR_QODB_READY) { /* save mailbox, which contains a list of completed commands */ bcopy((void *)(uintptr_t)(volatile void *)sc->amr_mailbox, mbsave, sizeof(*mbsave)); /* acknowledge interrupt */ AMR_QPUT_ODB(sc, AMR_QODB_READY); /* acknowledge that we have the commands */ AMR_QPUT_IDB(sc, sc->amr_mailboxphys | AMR_QIDB_ACK); #ifndef AMR_QUARTZ_GOFASTER /* * This waits for the controller to notice that we've taken the * command from it. It's very inefficient, and we shouldn't do it, * but if we remove this code, we stop completing commands under * load. * * Peter J says we shouldn't do this. The documentation says we * should. Who is right? */ while(AMR_QGET_IDB(sc) & AMR_QIDB_ACK) ; /* XXX aiee! what if it dies? */ #endif worked = 1; /* got some work */ } splx(s); return(worked); } static int amr_std_get_work(struct amr_softc *sc, struct amr_mailbox *mbsave) { int s, worked; u_int8_t istat; debug_called(3); worked = 0; s = splbio(); /* check for valid interrupt status */ istat = AMR_SGET_ISTAT(sc); if ((istat & AMR_SINTR_VALID) != 0) { AMR_SPUT_ISTAT(sc, istat); /* ack interrupt status */ /* save mailbox, which contains a list of completed commands */ bcopy((void *)(uintptr_t)(volatile void *)sc->amr_mailbox, mbsave, sizeof(*mbsave)); AMR_SACK_INTERRUPT(sc); /* acknowledge we have the mailbox */ worked = 1; } splx(s); return(worked); } /******************************************************************************** * Notify the controller of the mailbox location. */ static void amr_std_attach_mailbox(struct amr_softc *sc) { /* program the mailbox physical address */ AMR_SBYTE_SET(sc, AMR_SMBOX_0, sc->amr_mailboxphys & 0xff); AMR_SBYTE_SET(sc, AMR_SMBOX_1, (sc->amr_mailboxphys >> 8) & 0xff); AMR_SBYTE_SET(sc, AMR_SMBOX_2, (sc->amr_mailboxphys >> 16) & 0xff); AMR_SBYTE_SET(sc, AMR_SMBOX_3, (sc->amr_mailboxphys >> 24) & 0xff); AMR_SBYTE_SET(sc, AMR_SMBOX_ENABLE, AMR_SMBOX_ADDR); /* clear any outstanding interrupt and enable interrupts proper */ AMR_SACK_INTERRUPT(sc); AMR_SENABLE_INTR(sc); } #ifdef AMR_BOARD_INIT /******************************************************************************** * Initialise the controller */ static int amr_quartz_init(struct amr_softc *sc) { int status, ostatus; device_printf(sc->amr_dev, "initial init status %x\n", AMR_QGET_INITSTATUS(sc)); AMR_QRESET(sc); ostatus = 0xff; while ((status = AMR_QGET_INITSTATUS(sc)) != AMR_QINIT_DONE) { if (status != ostatus) { device_printf(sc->amr_dev, "(%x) %s\n", status, amr_describe_code(amr_table_qinit, status)); ostatus = status; } switch (status) { case AMR_QINIT_NOMEM: return(ENOMEM); case AMR_QINIT_SCAN: /* XXX we could print channel/target here */ break; } } return(0); } static int amr_std_init(struct amr_softc *sc) { int status, ostatus; device_printf(sc->amr_dev, "initial init status %x\n", AMR_SGET_INITSTATUS(sc)); AMR_SRESET(sc); ostatus = 0xff; while ((status = AMR_SGET_INITSTATUS(sc)) != AMR_SINIT_DONE) { if (status != ostatus) { device_printf(sc->amr_dev, "(%x) %s\n", status, amr_describe_code(amr_table_sinit, status)); ostatus = status; } switch (status) { case AMR_SINIT_NOMEM: return(ENOMEM); case AMR_SINIT_INPROG: /* XXX we could print channel/target here? */ break; } } return(0); } #endif /******************************************************************************** ******************************************************************************** Debugging ******************************************************************************** ********************************************************************************/ /******************************************************************************** * Identify the controller and print some information about it. */ static void amr_describe_controller(struct amr_softc *sc) { struct amr_prodinfo *ap; struct amr_enquiry *ae; char *prod; /* * Try to get 40LD product info, which tells us what the card is labelled as. */ if ((ap = amr_enquiry(sc, 2048, AMR_CMD_CONFIG, AMR_CONFIG_PRODUCT_INFO, 0)) != NULL) { device_printf(sc->amr_dev, " Firmware %.16s, BIOS %.16s, %dMB RAM\n", ap->ap_product, ap->ap_firmware, ap->ap_bios, ap->ap_memsize); free(ap, M_DEVBUF); return; } /* * Try 8LD extended ENQUIRY to get controller signature, and use lookup table. */ if ((ae = (struct amr_enquiry *)amr_enquiry(sc, 2048, AMR_CMD_EXT_ENQUIRY2, 0, 0)) != NULL) { prod = amr_describe_code(amr_table_adaptertype, ae->ae_signature); } else if ((ae = (struct amr_enquiry *)amr_enquiry(sc, 2048, AMR_CMD_ENQUIRY, 0, 0)) != NULL) { /* * Try to work it out based on the PCI signatures. */ switch (pci_get_device(sc->amr_dev)) { case 0x9010: prod = "Series 428"; break; case 0x9060: prod = "Series 434"; break; default: prod = "unknown controller"; break; } } else { prod = "unsupported controller"; } /* * HP NetRaid controllers have a special encoding of the firmware and * BIOS versions. The AMI version seems to have it as strings whereas * the HP version does it with a leading uppercase character and two * binary numbers. */ if(ae->ae_adapter.aa_firmware[2] >= 'A' && ae->ae_adapter.aa_firmware[2] <= 'Z' && ae->ae_adapter.aa_firmware[1] < ' ' && ae->ae_adapter.aa_firmware[0] < ' ' && ae->ae_adapter.aa_bios[2] >= 'A' && ae->ae_adapter.aa_bios[2] <= 'Z' && ae->ae_adapter.aa_bios[1] < ' ' && ae->ae_adapter.aa_bios[0] < ' ') { /* this looks like we have an HP NetRaid version of the MegaRaid */ if(ae->ae_signature == AMR_SIG_438) { /* the AMI 438 is a NetRaid 3si in HP-land */ prod = "HP NetRaid 3si"; } device_printf(sc->amr_dev, "<%s> Firmware %c.%02d.%02d, BIOS %c.%02d.%02d, %dMB RAM\n", prod, ae->ae_adapter.aa_firmware[2], ae->ae_adapter.aa_firmware[1], ae->ae_adapter.aa_firmware[0], ae->ae_adapter.aa_bios[2], ae->ae_adapter.aa_bios[1], ae->ae_adapter.aa_bios[0], ae->ae_adapter.aa_memorysize); } else { device_printf(sc->amr_dev, "<%s> Firmware %.4s, BIOS %.4s, %dMB RAM\n", prod, ae->ae_adapter.aa_firmware, ae->ae_adapter.aa_bios, ae->ae_adapter.aa_memorysize); } free(ae, M_DEVBUF); } #ifdef AMR_DEBUG /******************************************************************************** * Print the command (ac) in human-readable format */ #if 0 static void amr_printcommand(struct amr_command *ac) { struct amr_softc *sc = ac->ac_sc; struct amr_sgentry *sg; int i; device_printf(sc->amr_dev, "cmd %x ident %d drive %d\n", ac->ac_mailbox.mb_command, ac->ac_mailbox.mb_ident, ac->ac_mailbox.mb_drive); device_printf(sc->amr_dev, "blkcount %d lba %d\n", ac->ac_mailbox.mb_blkcount, ac->ac_mailbox.mb_lba); device_printf(sc->amr_dev, "virtaddr %p length %lu\n", ac->ac_data, (unsigned long)ac->ac_length); device_printf(sc->amr_dev, "sg physaddr %08x nsg %d\n", ac->ac_mailbox.mb_physaddr, ac->ac_mailbox.mb_nsgelem); device_printf(sc->amr_dev, "ccb %p bio %p\n", ac->ac_ccb_data, ac->ac_bio); /* get base address of s/g table */ sg = sc->amr_sgtable + (ac->ac_slot * AMR_NSEG); for (i = 0; i < ac->ac_mailbox.mb_nsgelem; i++, sg++) device_printf(sc->amr_dev, " %x/%d\n", sg->sg_addr, sg->sg_count); } #endif #endif