/* $OpenBSD: ami.c,v 1.106 2005/12/21 12:26:24 dlg Exp $ */ /* * Copyright (c) 2001 Michael Shalayeff * Copyright (c) 2005 Marco Peereboom * All rights reserved. * * The SCSI emulation layer is derived from gdt(4) driver, * Copyright (c) 1999, 2000 Niklas Hallqvist. 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 ``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 HIS RELATIVES 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 MIND, 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. */ /* * American Megatrends Inc. MegaRAID controllers driver * * This driver was made because these ppl and organizations * donated hardware and provided documentation: * * - 428 model card * John Kerbawy, Stephan Matis, Mark Stovall; * * - 467 and 475 model cards, docs * American Megatrends Inc.; * * - uninterruptable electric power for cvs * Theo de Raadt. */ #include "bio.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #if NBIO > 0 #include #endif /*#define AMI_DEBUG */ #ifdef AMI_DEBUG #define AMI_DPRINTF(m,a) do { if (ami_debug & (m)) printf a; } while (0) #define AMI_D_CMD 0x0001 #define AMI_D_INTR 0x0002 #define AMI_D_MISC 0x0004 #define AMI_D_DMA 0x0008 #define AMI_D_IOCTL 0x0010 int ami_debug = 0 | AMI_D_CMD | AMI_D_INTR | AMI_D_MISC /* | AMI_D_DMA */ /* | AMI_D_IOCTL */ ; #else #define AMI_DPRINTF(m,a) /* m, a */ #endif struct cfdriver ami_cd = { NULL, "ami", DV_DULL }; int ami_scsi_cmd(struct scsi_xfer *); int ami_scsi_ioctl(struct scsi_link *, u_long, caddr_t, int, struct proc *); void amiminphys(struct buf *bp); struct scsi_adapter ami_switch = { ami_scsi_cmd, amiminphys, 0, 0, ami_scsi_ioctl }; struct scsi_device ami_dev = { NULL, NULL, NULL, NULL }; int ami_scsi_raw_cmd(struct scsi_xfer *); struct scsi_adapter ami_raw_switch = { ami_scsi_raw_cmd, amiminphys, 0, 0, }; struct scsi_device ami_raw_dev = { NULL, NULL, NULL, NULL }; struct ami_ccb *ami_get_ccb(struct ami_softc *); void ami_put_ccb(struct ami_ccb *); u_int32_t ami_read(struct ami_softc *, bus_size_t); void ami_write(struct ami_softc *, bus_size_t, u_int32_t); void ami_copyhds(struct ami_softc *, const u_int32_t *, const u_int8_t *, const u_int8_t *); struct ami_mem *ami_allocmem(struct ami_softc *, size_t); void ami_freemem(struct ami_softc *, struct ami_mem *); void ami_stimeout(void *); int ami_cmd(struct ami_ccb *, int, int); int ami_start(struct ami_ccb *, int); int ami_done(struct ami_softc *, int); void ami_copy_internal_data(struct scsi_xfer *, void *, size_t); int ami_inquire(struct ami_softc *, u_int8_t); #if NBIO > 0 int ami_mgmt(struct ami_softc *, u_int8_t, u_int8_t, u_int8_t, u_int8_t, size_t, void *); int ami_drv_inq(struct ami_softc *, u_int8_t, u_int8_t, u_int8_t, void *); int ami_ioctl(struct device *, u_long, caddr_t); int ami_ioctl_inq(struct ami_softc *, struct bioc_inq *); int ami_vol(struct ami_softc *, struct bioc_vol *, struct ami_big_diskarray *); int ami_disk(struct ami_softc *, struct bioc_disk *, struct ami_big_diskarray *); int ami_ioctl_vol(struct ami_softc *, struct bioc_vol *); int ami_ioctl_disk(struct ami_softc *, struct bioc_disk *); int ami_ioctl_alarm(struct ami_softc *, struct bioc_alarm *); int ami_ioctl_setstate(struct ami_softc *, struct bioc_setstate *); #endif /* NBIO > 0 */ struct ami_ccb * ami_get_ccb(struct ami_softc *sc) { struct ami_ccb *ccb; ccb = TAILQ_LAST(&sc->sc_free_ccb, ami_queue_head); if (ccb) { TAILQ_REMOVE(&sc->sc_free_ccb, ccb, ccb_link); ccb->ccb_state = AMI_CCB_READY; } return (ccb); } void ami_put_ccb(struct ami_ccb *ccb) { struct ami_softc *sc = ccb->ccb_sc; ccb->ccb_state = AMI_CCB_FREE; ccb->ccb_wakeup = 0; ccb->ccb_data = NULL; ccb->ccb_xs = NULL; TAILQ_INSERT_TAIL(&sc->sc_free_ccb, ccb, ccb_link); } u_int32_t ami_read(struct ami_softc *sc, bus_size_t r) { u_int32_t rv; bus_space_barrier(sc->sc_iot, sc->sc_ioh, r, 4, BUS_SPACE_BARRIER_READ); rv = bus_space_read_4(sc->sc_iot, sc->sc_ioh, r); AMI_DPRINTF(AMI_D_CMD, ("ari 0x%x 0x08%x ", r, rv)); return (rv); } void ami_write(struct ami_softc *sc, bus_size_t r, u_int32_t v) { AMI_DPRINTF(AMI_D_CMD, ("awo 0x%x 0x%08x", r, v)); bus_space_write_4(sc->sc_iot, sc->sc_ioh, r, v); bus_space_barrier(sc->sc_iot, sc->sc_ioh, r, 4, BUS_SPACE_BARRIER_WRITE); } struct ami_mem * ami_allocmem(struct ami_softc *sc, size_t size) { struct ami_mem *am; int nsegs; am = malloc(sizeof(struct ami_mem), M_DEVBUF, M_NOWAIT); if (am == NULL) return (NULL); memset(am, 0, sizeof(struct ami_mem)); am->am_size = size; if (bus_dmamap_create(sc->sc_dmat, size, 1, size, 0, BUS_DMA_NOWAIT | BUS_DMA_ALLOCNOW, &am->am_map) != 0) goto amfree; if (bus_dmamem_alloc(sc->sc_dmat, size, PAGE_SIZE, 0, &am->am_seg, 1, &nsegs, BUS_DMA_NOWAIT) != 0) goto destroy; if (bus_dmamem_map(sc->sc_dmat, &am->am_seg, nsegs, size, &am->am_kva, BUS_DMA_NOWAIT) != 0) goto free; if (bus_dmamap_load(sc->sc_dmat, am->am_map, am->am_kva, size, NULL, BUS_DMA_NOWAIT) != 0) goto unmap; memset(am->am_kva, 0, size); return (am); unmap: bus_dmamem_unmap(sc->sc_dmat, am->am_kva, size); free: bus_dmamem_free(sc->sc_dmat, &am->am_seg, 1); destroy: bus_dmamap_destroy(sc->sc_dmat, am->am_map); amfree: free(am, M_DEVBUF); return (NULL); } void ami_freemem(struct ami_softc *sc, struct ami_mem *am) { bus_dmamap_unload(sc->sc_dmat, am->am_map); bus_dmamem_unmap(sc->sc_dmat, am->am_kva, am->am_size); bus_dmamem_free(sc->sc_dmat, &am->am_seg, 1); bus_dmamap_destroy(sc->sc_dmat, am->am_map); free(am, M_DEVBUF); } void ami_copyhds(struct ami_softc *sc, const u_int32_t *sizes, const u_int8_t *props, const u_int8_t *stats) { int i; for (i = 0; i < sc->sc_nunits; i++) { sc->sc_hdr[i].hd_present = 1; sc->sc_hdr[i].hd_is_logdrv = 1; sc->sc_hdr[i].hd_size = letoh32(sizes[i]); sc->sc_hdr[i].hd_prop = props[i]; sc->sc_hdr[i].hd_stat = stats[i]; } } int ami_attach(struct ami_softc *sc) { struct ami_rawsoftc *rsc; struct ami_ccb *ccb; struct ami_iocmd *cmd; struct ami_ccbmem *ccbmem, *mem; struct ami_mem *am; const char *p; int i, error; /* u_int32_t *pp; */ am = ami_allocmem(sc, NBPG); if (am == NULL) { printf(": unable to allocate init data\n"); return (1); } sc->sc_mbox_am = ami_allocmem(sc, sizeof(struct ami_iocmd)); if (sc->sc_mbox_am == NULL) { printf(": unable to allocate mbox\n"); goto free_idata; } sc->sc_mbox = (volatile struct ami_iocmd *)AMIMEM_KVA(sc->sc_mbox_am); sc->sc_mbox_pa = htole32(AMIMEM_DVA(sc->sc_mbox_am)); AMI_DPRINTF(AMI_D_CMD, ("mbox_pa=%llx ", sc->sc_mbox_pa)); sc->sc_ccbmem_am = ami_allocmem(sc, sizeof(struct ami_ccbmem) * AMI_MAXCMDS); if (sc->sc_ccbmem_am == NULL) { printf(": unable to allocate ccb dmamem\n"); goto free_mbox; } ccbmem = AMIMEM_KVA(sc->sc_ccbmem_am); TAILQ_INIT(&sc->sc_ccbq); TAILQ_INIT(&sc->sc_ccbdone); TAILQ_INIT(&sc->sc_free_ccb); for (i = 0; i < AMI_MAXCMDS; i++) { ccb = &sc->sc_ccbs[i]; mem = &ccbmem[i]; error = bus_dmamap_create(sc->sc_dmat, AMI_MAXFER, AMI_MAXOFFSETS, AMI_MAXFER, 0, BUS_DMA_NOWAIT | BUS_DMA_ALLOCNOW, &ccb->ccb_dmamap); if (error) { printf(": cannot create ccb dmamap (%d)\n", error); goto destroy; } ccb->ccb_sc = sc; ccb->ccb_state = AMI_CCB_FREE; ccb->ccb_cmd.acc_id = i + 1; ccb->ccb_offset = sizeof(struct ami_ccbmem) * i; ccb->ccb_pt = &mem->cd_pt; ccb->ccb_ptpa = htole32(AMIMEM_DVA(sc->sc_ccbmem_am) + ccb->ccb_offset); ccb->ccb_sglist = mem->cd_sg; ccb->ccb_sglistpa = htole32(AMIMEM_DVA(sc->sc_ccbmem_am) + ccb->ccb_offset + sizeof(struct ami_passthrough)); TAILQ_INSERT_TAIL(&sc->sc_free_ccb, ccb, ccb_link); } timeout_set(&sc->sc_poll_tmo, (void (*)(void *))ami_intr, sc); (sc->sc_init)(sc); { paddr_t pa = htole32(AMIMEM_DVA(am)); int s; s = splbio(); ccb = ami_get_ccb(sc); cmd = &ccb->ccb_cmd; /* try FC inquiry first */ cmd->acc_cmd = AMI_FCOP; cmd->acc_io.aio_channel = AMI_FC_EINQ3; cmd->acc_io.aio_param = AMI_FC_EINQ3_SOLICITED_FULL; cmd->acc_io.aio_data = pa; if (ami_cmd(ccb, BUS_DMA_NOWAIT, 1) == 0) { struct ami_fc_einquiry *einq = AMIMEM_KVA(am); struct ami_fc_prodinfo *pi = AMIMEM_KVA(am); sc->sc_nunits = einq->ain_nlogdrv; ami_copyhds(sc, einq->ain_ldsize, einq->ain_ldprop, einq->ain_ldstat); ccb = ami_get_ccb(sc); cmd = &ccb->ccb_cmd; cmd->acc_cmd = AMI_FCOP; cmd->acc_io.aio_channel = AMI_FC_PRODINF; cmd->acc_io.aio_param = 0; cmd->acc_io.aio_data = pa; if (ami_cmd(ccb, BUS_DMA_NOWAIT, 1) == 0) { sc->sc_maxunits = AMI_BIG_MAX_LDRIVES; bcopy (pi->api_fwver, sc->sc_fwver, 16); sc->sc_fwver[15] = '\0'; bcopy (pi->api_biosver, sc->sc_biosver, 16); sc->sc_biosver[15] = '\0'; sc->sc_channels = pi->api_channels; sc->sc_targets = pi->api_fcloops; sc->sc_memory = letoh16(pi->api_ramsize); sc->sc_maxcmds = pi->api_maxcmd; p = "FC loop"; } } if (sc->sc_maxunits == 0) { struct ami_inquiry *inq = AMIMEM_KVA(am); ccb = ami_get_ccb(sc); cmd = &ccb->ccb_cmd; cmd->acc_cmd = AMI_EINQUIRY; cmd->acc_io.aio_channel = 0; cmd->acc_io.aio_param = 0; cmd->acc_io.aio_data = pa; if (ami_cmd(ccb, BUS_DMA_NOWAIT, 1) != 0) { ccb = ami_get_ccb(sc); cmd = &ccb->ccb_cmd; cmd->acc_cmd = AMI_INQUIRY; cmd->acc_io.aio_channel = 0; cmd->acc_io.aio_param = 0; cmd->acc_io.aio_data = pa; if (ami_cmd(ccb, BUS_DMA_NOWAIT, 1) != 0) { splx(s); printf(": cannot do inquiry\n"); goto destroy; } } sc->sc_maxunits = AMI_MAX_LDRIVES; sc->sc_nunits = inq->ain_nlogdrv; ami_copyhds(sc, inq->ain_ldsize, inq->ain_ldprop, inq->ain_ldstat); bcopy (inq->ain_fwver, sc->sc_fwver, 4); sc->sc_fwver[4] = '\0'; bcopy (inq->ain_biosver, sc->sc_biosver, 4); sc->sc_biosver[4] = '\0'; sc->sc_channels = inq->ain_channels; sc->sc_targets = inq->ain_targets; sc->sc_memory = inq->ain_ramsize; sc->sc_maxcmds = inq->ain_maxcmd; p = "target"; } #if 0 /* FIXME need to find a way to detect if fw supports this * calling it this way crashes fw when io is ran to * multiple logical disks */ /* reset the IO completion values to 0 * the firmware either has at least pp[0] IOs outstanding * -or- * it times out pp[1] us before it completes any IO * if the values remain unchanged it locksteps the driver * to a maximum of 4 outstanding IOs and it hits the 5us timer * continuously (these are the default values) * this trick only works with firmwares newer than 5/13/05 * Setting the values outright will hang old firmwares so * we need to read them first before setting them. */ ccb = ami_get_ccb(sc); ccb->ccb_data = NULL; cmd = &ccb->ccb_cmd; cmd->acc_cmd = AMI_MISC; cmd->acc_io.aio_channel = AMI_GET_IO_CMPL; /* sub opcode */ cmd->acc_io.aio_param = 0; cmd->acc_io.aio_data = pa; if (ami_cmd(ccb, BUS_DMA_NOWAIT, 1) != 0) { AMI_DPRINTF(AMI_D_MISC, ("getting io completion values" " failed\n")); } else { ccb = ami_get_ccb(sc); ccb->ccb_data = NULL; cmd = &ccb->ccb_cmd; cmd->acc_cmd = AMI_MISC; cmd->acc_io.aio_channel = AMI_SET_IO_CMPL; cmd->acc_io.aio_param = 0; cmd->acc_io.aio_data = pa; /* set parameters */ pp = AMIMEM_KVA(am); pp[0] = 0; /* minimal outstanding commands, 0 disable */ pp[1] = 0; /* maximal timeout in us, 0 disable */ if (ami_cmd(ccb, BUS_DMA_NOWAIT, 1) != 0) { AMI_DPRINTF(AMI_D_MISC, ("setting io completion" " values failed\n")); } else { AMI_DPRINTF(AMI_D_MISC, ("setting io completion" " values succeeded\n")); } } #endif if (sc->sc_flags & AMI_BROKEN) { sc->sc_link.openings = 1; sc->sc_maxcmds = 1; sc->sc_maxunits = 1; } else { sc->sc_maxunits = AMI_BIG_MAX_LDRIVES; if (sc->sc_maxcmds > AMI_MAXCMDS) sc->sc_maxcmds = AMI_MAXCMDS; /* * Reserve ccb's for ioctl's and raw commands to * processors/enclosures by lowering the number of * openings available for logical units. */ sc->sc_maxcmds -= AMI_MAXIOCTLCMDS + AMI_MAXPROCS * AMI_MAXRAWCMDS * sc->sc_channels; if (sc->sc_nunits) sc->sc_link.openings = sc->sc_maxcmds / sc->sc_nunits; else sc->sc_link.openings = sc->sc_maxcmds; } splx(s); } ami_freemem(sc, am); /* hack for hp netraid version encoding */ if ('A' <= sc->sc_fwver[2] && sc->sc_fwver[2] <= 'Z' && sc->sc_fwver[1] < ' ' && sc->sc_fwver[0] < ' ' && 'A' <= sc->sc_biosver[2] && sc->sc_biosver[2] <= 'Z' && sc->sc_biosver[1] < ' ' && sc->sc_biosver[0] < ' ') { snprintf(sc->sc_fwver, sizeof sc->sc_fwver, "%c.%02d.%02d", sc->sc_fwver[2], sc->sc_fwver[1], sc->sc_fwver[0]); snprintf(sc->sc_biosver, sizeof sc->sc_biosver, "%c.%02d.%02d", sc->sc_biosver[2], sc->sc_biosver[1], sc->sc_biosver[0]); } /* TODO: fetch & print cache strategy */ /* TODO: fetch & print scsi and raid info */ sc->sc_link.device = &ami_dev; sc->sc_link.adapter_softc = sc; sc->sc_link.adapter = &ami_switch; sc->sc_link.adapter_target = sc->sc_maxunits; sc->sc_link.adapter_buswidth = sc->sc_maxunits; #ifdef AMI_DEBUG printf(": FW %s, BIOS v%s, %dMB RAM\n" "%s: %d channels, %d %ss, %d logical drives, " "openings %d, max commands %d, quirks: %04x\n", sc->sc_fwver, sc->sc_biosver, sc->sc_memory, sc->sc_dev.dv_xname, sc->sc_channels, sc->sc_targets, p, sc->sc_nunits, sc->sc_link.openings, sc->sc_maxcmds, sc->sc_flags); #else printf(": FW %s, BIOS v%s, %dMB RAM\n" "%s: %d channels, %d %ss, %d logical drives\n", sc->sc_fwver, sc->sc_biosver, sc->sc_memory, sc->sc_dev.dv_xname, sc->sc_channels, sc->sc_targets, p, sc->sc_nunits); #endif /* AMI_DEBUG */ if (sc->sc_flags & AMI_BROKEN && sc->sc_nunits > 1) printf("%s: firmware buggy, limiting access to first logical " "disk\n", sc->sc_dev.dv_xname); #if NBIO > 0 if (bio_register(&sc->sc_dev, ami_ioctl) != 0) printf("%s: controller registration failed", sc->sc_dev.dv_xname); else sc->sc_ioctl = ami_ioctl; #endif /* NBIO > 0 */ config_found(&sc->sc_dev, &sc->sc_link, scsiprint); /* can't do pass-through on broken device for now */ if (sc->sc_flags & AMI_BROKEN) return (0); rsc = malloc(sizeof(struct ami_rawsoftc) * sc->sc_channels, M_DEVBUF, M_NOWAIT); if (!rsc) { printf("%s: no memory for raw interface\n", sc->sc_dev.dv_xname); return (0); } bzero(rsc, sizeof(struct ami_rawsoftc) * sc->sc_channels); for (sc->sc_rawsoftcs = rsc; rsc < &sc->sc_rawsoftcs[sc->sc_channels]; rsc++) { /* TODO fetch and print channel properties */ rsc->sc_softc = sc; rsc->sc_channel = rsc - sc->sc_rawsoftcs; rsc->sc_link.device = &ami_raw_dev; rsc->sc_link.openings = AMI_MAXRAWCMDS; rsc->sc_link.adapter_softc = rsc; rsc->sc_link.adapter = &ami_raw_switch; rsc->sc_proctarget = -1; /* TODO fetch it from the controller */ rsc->sc_link.adapter_target = 16; rsc->sc_link.adapter_buswidth = 16; config_found(&sc->sc_dev, &rsc->sc_link, scsiprint); } return (0); destroy: for (ccb = &sc->sc_ccbs[AMI_MAXCMDS - 1]; ccb > sc->sc_ccbs; ccb--) if (ccb->ccb_dmamap) bus_dmamap_destroy(sc->sc_dmat, ccb->ccb_dmamap); ami_freemem(sc, sc->sc_ccbmem_am); free_mbox: ami_freemem(sc, sc->sc_mbox_am); free_idata: ami_freemem(sc, am); return (1); } int ami_quartz_init(struct ami_softc *sc) { ami_write(sc, AMI_QIDB, 0); return (0); } int ami_quartz_exec(struct ami_softc *sc, struct ami_iocmd *cmd) { u_int32_t i; i = 0; while (sc->sc_mbox->acc_busy && (i < AMI_MAX_BUSYWAIT)) { delay(1); i++; } if (sc->sc_mbox->acc_busy) { AMI_DPRINTF(AMI_D_CMD, ("mbox_busy ")); return (EBUSY); } memcpy((struct ami_iocmd *)sc->sc_mbox, cmd, 16); bus_dmamap_sync(sc->sc_dmat, AMIMEM_MAP(sc->sc_mbox_am), 0, sizeof(struct ami_iocmd), BUS_DMASYNC_PREWRITE|BUS_DMASYNC_PREREAD); sc->sc_mbox->acc_busy = 1; sc->sc_mbox->acc_poll = 0; sc->sc_mbox->acc_ack = 0; ami_write(sc, AMI_QIDB, sc->sc_mbox_pa | htole32(AMI_QIDB_EXEC)); return (0); } int ami_quartz_done(struct ami_softc *sc, struct ami_iocmd *mbox) { u_int32_t i, n; u_int8_t nstat, status; u_int8_t completed[AMI_MAXSTATACK]; if (ami_read(sc, AMI_QODB) != AMI_QODB_READY) return (0); /* nothing to do */ ami_write(sc, AMI_QODB, AMI_QODB_READY); /* * The following sequence is not supposed to have a timeout clause * since the firmware has a "guarantee" that all commands will * complete. The choice is either panic or hoping for a miracle * and that the IOs will complete much later. */ i = 0; while ((nstat = sc->sc_mbox->acc_nstat) == 0xff) { bus_dmamap_sync(sc->sc_dmat, AMIMEM_MAP(sc->sc_mbox_am), 0, sizeof(struct ami_iocmd), BUS_DMASYNC_POSTREAD); delay(1); if (i++ > 1000000) return (0); /* nothing to do */ } sc->sc_mbox->acc_nstat = 0xff; bus_dmamap_sync(sc->sc_dmat, AMIMEM_MAP(sc->sc_mbox_am), 0, sizeof(struct ami_iocmd), BUS_DMASYNC_POSTWRITE); /* wait until fw wrote out all completions */ i = 0; AMI_DPRINTF(AMI_D_CMD, ("aqd %d ", nstat)); for (n = 0; n < nstat; n++) { bus_dmamap_sync(sc->sc_dmat, AMIMEM_MAP(sc->sc_mbox_am), 0, sizeof(struct ami_iocmd), BUS_DMASYNC_PREREAD); while ((completed[n] = sc->sc_mbox->acc_cmplidl[n]) == 0xff) { delay(1); if (i++ > 1000000) return (0); /* nothing to do */ } sc->sc_mbox->acc_cmplidl[n] = 0xff; bus_dmamap_sync(sc->sc_dmat, AMIMEM_MAP(sc->sc_mbox_am), 0, sizeof(struct ami_iocmd), BUS_DMASYNC_POSTWRITE); } /* this should never happen, someone screwed up the completion status */ if ((status = sc->sc_mbox->acc_status) == 0xff) panic("%s: status 0xff from the firmware", sc->sc_dev.dv_xname); sc->sc_mbox->acc_status = 0xff; /* copy mailbox to temporary one and fixup other changed values */ bus_dmamap_sync(sc->sc_dmat, AMIMEM_MAP(sc->sc_mbox_am), 0, 16, BUS_DMASYNC_POSTWRITE); memcpy(mbox, (struct ami_iocmd *)sc->sc_mbox, 16); mbox->acc_nstat = nstat; mbox->acc_status = status; for (n = 0; n < nstat; n++) mbox->acc_cmplidl[n] = completed[n]; /* ack interrupt */ ami_write(sc, AMI_QIDB, AMI_QIDB_ACK); return (1); /* ready to complete all IOs in acc_cmplidl */ } int ami_quartz_poll(struct ami_softc *sc, struct ami_iocmd *cmd) { /* struct scsi_xfer *xs = ccb->ccb_xs; */ u_int32_t i; u_int8_t status, ready; if (sc->sc_dis_poll) return (1); /* fail */ i = 0; while (sc->sc_mbox->acc_busy && (i < AMI_MAX_BUSYWAIT)) { delay(1); i++; } if (sc->sc_mbox->acc_busy) { AMI_DPRINTF(AMI_D_CMD, ("mbox_busy ")); return (EBUSY); } memcpy((struct ami_iocmd *)sc->sc_mbox, cmd, 16); bus_dmamap_sync(sc->sc_dmat, AMIMEM_MAP(sc->sc_mbox_am), 0, 16, BUS_DMASYNC_PREWRITE|BUS_DMASYNC_PREREAD); sc->sc_mbox->acc_id = 0xfe; sc->sc_mbox->acc_busy = 1; sc->sc_mbox->acc_poll = 0; sc->sc_mbox->acc_ack = 0; sc->sc_mbox->acc_nstat = 0xff; sc->sc_mbox->acc_status = 0xff; /* send command to firmware */ ami_write(sc, AMI_QIDB, sc->sc_mbox_pa | htole32(AMI_QIDB_EXEC)); while ((sc->sc_mbox->acc_nstat == 0xff) && (i < AMI_MAX_POLLWAIT)) { delay(1); i++; } if (i >= AMI_MAX_POLLWAIT) { printf("%s: command not accepted, polling disabled\n", sc->sc_dev.dv_xname); sc->sc_dis_poll = 1; return (1); } sc->sc_mbox->acc_nstat = 0xff; while ((sc->sc_mbox->acc_status == 0xff) && (i < AMI_MAX_POLLWAIT)) { delay(1); i++; } if (i >= AMI_MAX_POLLWAIT) { printf("%s: bad status, polling disabled\n", sc->sc_dev.dv_xname); sc->sc_dis_poll = 1; return (1); } status = sc->sc_mbox->acc_status; sc->sc_mbox->acc_status = 0xff; /* poll firmware */ while ((sc->sc_mbox->acc_poll != 0x77) && (i < AMI_MAX_POLLWAIT)) { delay(1); i++; } if (i >= AMI_MAX_POLLWAIT) { printf("%s: firmware didn't reply, polling disabled\n", sc->sc_dev.dv_xname); sc->sc_dis_poll = 1; return 1; } sc->sc_mbox->acc_poll = 0; sc->sc_mbox->acc_ack = 0x77; /* ack */ ami_write(sc, AMI_QIDB, sc->sc_mbox_pa | htole32(AMI_QIDB_ACK)); while((ami_read(sc, AMI_QIDB) & AMI_QIDB_ACK) && (i < AMI_MAX_POLLWAIT)) { delay(1); i++; } if (i >= AMI_MAX_POLLWAIT) { printf("%s: firmware didn't ack the ack, polling disabled\n", sc->sc_dev.dv_xname); sc->sc_dis_poll = 1; return (1); } ready = sc->sc_mbox->acc_cmplidl[0]; for (i = 0; i < AMI_MAXSTATACK; i++) sc->sc_mbox->acc_cmplidl[i] = 0xff; #if 0 /* FIXME */ /* am I a scsi command? if so complete it */ if (xs) { printf("sc "); if (!ami_done(sc, ready)) status = 0; else status = 1; /* failed */ } else /* need to clean up ccb ourselves */ ami_put_ccb(ccb); #endif return (status); } int ami_schwartz_init(struct ami_softc *sc) { u_int32_t a = (u_int32_t)sc->sc_mbox_pa; bus_space_write_4(sc->sc_iot, sc->sc_ioh, AMI_SMBADDR, a); /* XXX 40bit address ??? */ bus_space_write_1(sc->sc_iot, sc->sc_ioh, AMI_SMBENA, 0); bus_space_write_1(sc->sc_iot, sc->sc_ioh, AMI_SCMD, AMI_SCMD_ACK); bus_space_write_1(sc->sc_iot, sc->sc_ioh, AMI_SIEM, AMI_SEIM_ENA | bus_space_read_1(sc->sc_iot, sc->sc_ioh, AMI_SIEM)); return (0); } int ami_schwartz_exec(struct ami_softc *sc, struct ami_iocmd *cmd) { if (bus_space_read_1(sc->sc_iot, sc->sc_ioh, AMI_SMBSTAT) & AMI_SMBST_BUSY) { AMI_DPRINTF(AMI_D_CMD, ("mbox_busy ")); return (EBUSY); } memcpy((struct ami_iocmd *)sc->sc_mbox, cmd, 16); sc->sc_mbox->acc_busy = 1; sc->sc_mbox->acc_poll = 0; sc->sc_mbox->acc_ack = 0; bus_space_write_1(sc->sc_iot, sc->sc_ioh, AMI_SCMD, AMI_SCMD_EXEC); return (0); } int ami_schwartz_done(struct ami_softc *sc, struct ami_iocmd *mbox) { u_int8_t stat; #if 0 /* do not scramble the busy mailbox */ if (sc->sc_mbox->acc_busy) return (0); #endif if (bus_space_read_1(sc->sc_iot, sc->sc_ioh, AMI_SMBSTAT) & AMI_SMBST_BUSY) return (0); stat = bus_space_read_1(sc->sc_iot, sc->sc_ioh, AMI_ISTAT); if (stat & AMI_ISTAT_PEND) { bus_space_write_1(sc->sc_iot, sc->sc_ioh, AMI_ISTAT, stat); *mbox = *sc->sc_mbox; AMI_DPRINTF(AMI_D_CMD, ("asd %d ", mbox->acc_nstat)); bus_space_write_1(sc->sc_iot, sc->sc_ioh, AMI_SCMD, AMI_SCMD_ACK); return (1); } return (0); } int ami_schwartz_poll(struct ami_softc *sc, struct ami_iocmd *mbox) { u_int8_t status; u_int32_t i; int rv; if (sc->sc_dis_poll) return (1); /* fail */ for (i = 0; i < AMI_MAX_POLLWAIT; i++) { if (!(bus_space_read_1(sc->sc_iot, sc->sc_ioh, AMI_SMBSTAT) & AMI_SMBST_BUSY)) break; delay(1); } if (i >= AMI_MAX_POLLWAIT) { AMI_DPRINTF(AMI_D_CMD, ("mbox_busy ")); return (EBUSY); } memcpy((struct ami_iocmd *)sc->sc_mbox, mbox, 16); bus_dmamap_sync(sc->sc_dmat, AMIMEM_MAP(sc->sc_mbox_am), 0, 16, BUS_DMASYNC_PREWRITE|BUS_DMASYNC_PREREAD); sc->sc_mbox->acc_busy = 1; sc->sc_mbox->acc_poll = 0; sc->sc_mbox->acc_ack = 0; /* send command to firmware */ bus_space_write_1(sc->sc_iot, sc->sc_ioh, AMI_SCMD, AMI_SCMD_EXEC); /* wait until no longer busy */ for (i = 0; i < AMI_MAX_POLLWAIT; i++) { if (!(bus_space_read_1(sc->sc_iot, sc->sc_ioh, AMI_SMBSTAT) & AMI_SMBST_BUSY)) break; delay(1); } if (i >= AMI_MAX_POLLWAIT) { printf("%s: command not accepted, polling disabled\n", sc->sc_dev.dv_xname); sc->sc_dis_poll = 1; return (1); /* fail */ } /* wait for interrupt bit */ for (i = 0; i < AMI_MAX_POLLWAIT; i++) { status = bus_space_read_1(sc->sc_iot, sc->sc_ioh, AMI_ISTAT); if (status & AMI_ISTAT_PEND) break; delay(1); } if (i >= AMI_MAX_POLLWAIT) { printf("%s: interrupt didn't arrive, polling disabled\n", sc->sc_dev.dv_xname); sc->sc_dis_poll = 1; return (1); /* fail */ } /* write ststus back to firmware */ bus_space_write_1(sc->sc_iot, sc->sc_ioh, AMI_ISTAT, status); /* copy mailbox and status back */ bus_dmamap_sync(sc->sc_dmat, AMIMEM_MAP(sc->sc_mbox_am), 0, sizeof(struct ami_iocmd), BUS_DMASYNC_PREREAD); *mbox = *sc->sc_mbox; rv = sc->sc_mbox->acc_status; /* ack interrupt */ bus_space_write_1(sc->sc_iot, sc->sc_ioh, AMI_SCMD, AMI_SCMD_ACK); return (rv); } int ami_cmd(struct ami_ccb *ccb, int flags, int wait) { struct ami_softc *sc = ccb->ccb_sc; bus_dmamap_t dmap = ccb->ccb_dmamap; int error = 0, i; if (ccb->ccb_data) { struct ami_iocmd *cmd = &ccb->ccb_cmd; bus_dma_segment_t *sgd; error = bus_dmamap_load(sc->sc_dmat, dmap, ccb->ccb_data, ccb->ccb_len, NULL, flags); if (error) { if (error == EFBIG) printf("more than %d dma segs\n", AMI_MAXOFFSETS); else printf("error %d loading dma map\n", error); ami_put_ccb(ccb); return (error); } if (cmd->acc_cmd == AMI_PASSTHRU) cmd->acc_passthru.apt_data = ccb->ccb_ptpa; sgd = dmap->dm_segs; AMI_DPRINTF(AMI_D_DMA, ("data=%p/%u<0x%lx/%u", ccb->ccb_data, ccb->ccb_len, sgd->ds_addr, sgd->ds_len)); if(dmap->dm_nsegs > 1) { struct ami_sgent *sgl = ccb->ccb_sglist; if (cmd->acc_cmd == AMI_PASSTHRU) { ccb->ccb_pt->apt_nsge = dmap->dm_nsegs; ccb->ccb_pt->apt_data = ccb->ccb_sglistpa; } else { cmd->acc_mbox.amb_nsge = dmap->dm_nsegs; cmd->acc_mbox.amb_data = ccb->ccb_sglistpa; } for (i = 0; i < dmap->dm_nsegs; i++, sgd++) { sgl[i].asg_addr = htole32(sgd->ds_addr); sgl[i].asg_len = htole32(sgd->ds_len); #ifdef AMI_DEBUG if (i) AMI_DPRINTF(AMI_D_DMA, (",0x%lx/%u", sgd->ds_addr, sgd->ds_len)); #endif } } else { if (cmd->acc_cmd == AMI_PASSTHRU) { ccb->ccb_pt->apt_nsge = 0; ccb->ccb_pt->apt_data = htole32(sgd->ds_addr); } else { cmd->acc_mbox.amb_nsge = 0; cmd->acc_mbox.amb_data = htole32(sgd->ds_addr); } } AMI_DPRINTF(AMI_D_DMA, ("> ")); bus_dmamap_sync(sc->sc_dmat, AMIMEM_MAP(sc->sc_ccbmem_am), ccb->ccb_offset, sizeof(struct ami_ccbmem), BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE); bus_dmamap_sync(sc->sc_dmat, dmap, 0, dmap->dm_mapsize, (ccb->ccb_dir == AMI_CCB_IN) ? BUS_DMASYNC_PREREAD : BUS_DMASYNC_PREWRITE); } else ccb->ccb_cmd.acc_mbox.amb_nsge = 0; if (wait) { AMI_DPRINTF(AMI_D_DMA, ("waiting ")); /* FIXME remove all wait out ami_start */ error = sc->sc_poll(sc, &ccb->ccb_cmd); #ifdef AMI_DEBUG if (error) AMI_DPRINTF(AMI_D_MISC, ("pf ")); #endif if (ccb->ccb_data) { bus_dmamap_sync(sc->sc_dmat, ccb->ccb_dmamap, 0, ccb->ccb_dmamap->dm_mapsize, (ccb->ccb_dir == AMI_CCB_IN) ? BUS_DMASYNC_POSTREAD : BUS_DMASYNC_POSTWRITE); bus_dmamap_sync(sc->sc_dmat, AMIMEM_MAP(sc->sc_ccbmem_am), ccb->ccb_offset, sizeof(struct ami_ccbmem), BUS_DMASYNC_POSTREAD | BUS_DMASYNC_POSTWRITE); bus_dmamap_unload(sc->sc_dmat, dmap); } if (ccb->ccb_wakeup) ccb->ccb_wakeup = 0; else ami_put_ccb(ccb); } else if ((error = ami_start(ccb, wait))) { AMI_DPRINTF(AMI_D_DMA, ("error=%d ", error)); __asm __volatile(".globl _bpamierr\n_bpamierr:"); if (ccb->ccb_data) { bus_dmamap_sync(sc->sc_dmat, ccb->ccb_dmamap, 0, ccb->ccb_dmamap->dm_mapsize, (ccb->ccb_dir == AMI_CCB_IN) ? BUS_DMASYNC_POSTREAD : BUS_DMASYNC_POSTWRITE); bus_dmamap_sync(sc->sc_dmat, AMIMEM_MAP(sc->sc_ccbmem_am), ccb->ccb_offset, sizeof(struct ami_ccbmem), BUS_DMASYNC_POSTREAD | BUS_DMASYNC_POSTWRITE); bus_dmamap_unload(sc->sc_dmat, dmap); } ami_put_ccb(ccb); } return (error); } int ami_start(struct ami_ccb *ccb, int wait) { struct ami_softc *sc = ccb->ccb_sc; struct ami_iocmd *cmd = &ccb->ccb_cmd; struct scsi_xfer *xs = ccb->ccb_xs; volatile struct ami_iocmd *mbox = sc->sc_mbox; int i; AMI_DPRINTF(AMI_D_CMD, ("start(%d) ", cmd->acc_id)); if (ccb->ccb_state != AMI_CCB_READY) { printf("%s: ccb %d not ready <%d>\n", sc->sc_dev.dv_xname, cmd->acc_id, ccb->ccb_state); return (EINVAL); } if (xs) timeout_set(&xs->stimeout, ami_stimeout, ccb); if (wait && mbox->acc_busy) { for (i = 100000; i-- && mbox->acc_busy; DELAY(10)); if (mbox->acc_busy) { AMI_DPRINTF(AMI_D_CMD, ("mbox_busy ")); return (EAGAIN); } } AMI_DPRINTF(AMI_D_CMD, ("exec ")); if (!(i = (sc->sc_exec)(sc, cmd))) { ccb->ccb_state = AMI_CCB_QUEUED; TAILQ_INSERT_TAIL(&sc->sc_ccbq, ccb, ccb_link); if (!wait) { #ifdef AMI_POLLING if (!timeout_pending(&sc->sc_poll_tmo)) timeout_add(&sc->sc_poll_tmo, 1); #endif if (xs) { struct timeval tv; /* add 5sec for whacky done() loops */ tv.tv_sec = 5 + xs->timeout / 1000; tv.tv_usec = 1000 * (xs->timeout % 1000); timeout_add(&xs->stimeout, tvtohz(&tv)); } } } else if (!wait && xs) { AMI_DPRINTF(AMI_D_CMD, ("2queue1(%d) ", cmd->acc_id)); ccb->ccb_state = AMI_CCB_PREQUEUED; timeout_add(&xs->stimeout, 1); return (0); } return (i); } /* FIXME timeouts should be rethought */ void ami_stimeout(void *v) { struct ami_ccb *ccb = v; struct ami_softc *sc = ccb->ccb_sc; struct scsi_xfer *xs = ccb->ccb_xs; struct ami_iocmd *cmd = &ccb->ccb_cmd; volatile struct ami_iocmd *mbox = sc->sc_mbox; int s; s = splbio(); switch (ccb->ccb_state) { case AMI_CCB_PREQUEUED: if (mbox->acc_busy) { timeout_add(&xs->stimeout, 1); break; } AMI_DPRINTF(AMI_D_CMD, ("requeue(%d) ", cmd->acc_id)); ccb->ccb_state = AMI_CCB_READY; if (ami_start(ccb, 0)) { AMI_DPRINTF(AMI_D_CMD, ("requeue(%d) again\n", cmd->acc_id)); ccb->ccb_state = AMI_CCB_PREQUEUED; timeout_add(&xs->stimeout, 1); } break; case AMI_CCB_QUEUED: /* XXX need to kill all cmds in the queue and reset the card */ printf("%s: timeout ccb %d\n", sc->sc_dev.dv_xname, cmd->acc_id); AMI_DPRINTF(AMI_D_CMD, ("timeout(%d) ", cmd->acc_id)); if (xs->cmd->opcode != PREVENT_ALLOW && xs->cmd->opcode != SYNCHRONIZE_CACHE) { bus_dmamap_sync(sc->sc_dmat, ccb->ccb_dmamap, 0, ccb->ccb_dmamap->dm_mapsize, (xs->flags & SCSI_DATA_IN) ? BUS_DMASYNC_POSTREAD : BUS_DMASYNC_POSTWRITE); bus_dmamap_unload(sc->sc_dmat, ccb->ccb_dmamap); } TAILQ_REMOVE(&sc->sc_ccbq, ccb, ccb_link); ami_put_ccb(ccb); xs->error = XS_TIMEOUT; xs->flags |= ITSDONE; scsi_done(xs); break; case AMI_CCB_FREE: case AMI_CCB_READY: panic("ami_stimeout(%d) botch", cmd->acc_id); } splx(s); } int ami_done(struct ami_softc *sc, int idx) { struct ami_ccb *ccb = &sc->sc_ccbs[idx - 1]; struct scsi_xfer *xs = ccb->ccb_xs; int s; AMI_DPRINTF(AMI_D_CMD, ("done(%d) ", ccb->ccb_cmd.acc_id)); if (ccb->ccb_state != AMI_CCB_QUEUED) { printf("%s: unqueued ccb %d ready, state = %d\n", sc->sc_dev.dv_xname, idx, ccb->ccb_state); return (1); } s = splbio(); ccb->ccb_state = AMI_CCB_READY; TAILQ_REMOVE(&sc->sc_ccbq, ccb, ccb_link); if (ccb->ccb_data != NULL) { bus_dmamap_sync(sc->sc_dmat, ccb->ccb_dmamap, 0, ccb->ccb_dmamap->dm_mapsize, (ccb->ccb_dir == AMI_CCB_IN) ? BUS_DMASYNC_POSTREAD : BUS_DMASYNC_POSTWRITE); bus_dmamap_sync(sc->sc_dmat, AMIMEM_MAP(sc->sc_ccbmem_am), ccb->ccb_offset, sizeof(struct ami_ccbmem), BUS_DMASYNC_POSTREAD | BUS_DMASYNC_POSTWRITE); bus_dmamap_unload(sc->sc_dmat, ccb->ccb_dmamap); } if (ccb->ccb_wakeup) { ccb->ccb_wakeup = 0; wakeup(ccb); } else ami_put_ccb(ccb); if (xs) { timeout_del(&xs->stimeout); xs->resid = 0; xs->flags |= ITSDONE; AMI_DPRINTF(AMI_D_CMD, ("scsi_done(%d) ", idx)); scsi_done(xs); } splx(s); return (0); } void amiminphys(struct buf *bp) { if (bp->b_bcount > AMI_MAXFER) bp->b_bcount = AMI_MAXFER; minphys(bp); } void ami_copy_internal_data(struct scsi_xfer *xs, void *v, size_t size) { size_t copy_cnt; AMI_DPRINTF(AMI_D_MISC, ("ami_copy_internal_data ")); if (!xs->datalen) printf("uio move not yet supported\n"); else { copy_cnt = MIN(size, xs->datalen); bcopy(v, xs->data, copy_cnt); } } int ami_scsi_raw_cmd(struct scsi_xfer *xs) { struct scsi_link *link = xs->sc_link; struct ami_rawsoftc *rsc = link->adapter_softc; struct ami_softc *sc = rsc->sc_softc; u_int8_t channel = rsc->sc_channel, target = link->target; struct device *dev = link->device_softc; struct ami_ccb *ccb; struct ami_iocmd *cmd; int error; int s; char type; AMI_DPRINTF(AMI_D_CMD, ("ami_scsi_raw_cmd ")); s = splbio(); if (!cold && target == rsc->sc_proctarget) strlcpy(rsc->sc_procdev, dev->dv_xname, sizeof(rsc->sc_procdev)); if (xs->cmdlen > AMI_MAX_CDB) { AMI_DPRINTF(AMI_D_CMD, ("CDB too big %p ", xs)); bzero(&xs->sense, sizeof(xs->sense)); xs->sense.error_code = SSD_ERRCODE_VALID | 0x70; xs->sense.flags = SKEY_ILLEGAL_REQUEST; xs->sense.add_sense_code = 0x20; /* illcmd, 0x24 illfield */ xs->error = XS_SENSE; scsi_done(xs); splx(s); return (COMPLETE); } xs->error = XS_NOERROR; if ((ccb = ami_get_ccb(sc)) == NULL) { xs->error = XS_DRIVER_STUFFUP; scsi_done(xs); splx(s); return (COMPLETE); } memset(ccb->ccb_pt, 0, sizeof(struct ami_passthrough)); ccb->ccb_xs = xs; ccb->ccb_len = xs->datalen; ccb->ccb_data = xs->data; ccb->ccb_dir = (xs->flags & SCSI_DATA_IN) ? AMI_CCB_IN : AMI_CCB_OUT; ccb->ccb_pt->apt_param = AMI_PTPARAM(AMI_TIMEOUT_6,1,0); ccb->ccb_pt->apt_channel = channel; ccb->ccb_pt->apt_target = target; bcopy(xs->cmd, ccb->ccb_pt->apt_cdb, AMI_MAX_CDB); ccb->ccb_pt->apt_ncdb = xs->cmdlen; ccb->ccb_pt->apt_nsense = AMI_MAX_SENSE; ccb->ccb_pt->apt_datalen = xs->datalen; cmd = &ccb->ccb_cmd; cmd->acc_cmd = AMI_PASSTHRU; if ((error = ami_cmd(ccb, ((xs->flags & SCSI_NOSLEEP) ? BUS_DMA_NOWAIT : BUS_DMA_WAITOK), xs->flags & SCSI_POLL))) { xs->error = XS_DRIVER_STUFFUP; scsi_done(xs); splx(s); return (COMPLETE); } if (xs->flags & SCSI_POLL) { if (xs->cmd->opcode == INQUIRY) { type = ((struct scsi_inquiry_data *)xs->data)->device & SID_TYPE; if (!(type == T_PROCESSOR || type == T_ENCLOSURE)) xs->error = XS_DRIVER_STUFFUP; else rsc->sc_proctarget = target; /* save target */ } scsi_done(xs); } splx(s); if (xs->flags & SCSI_POLL) return (COMPLETE); else return (SUCCESSFULLY_QUEUED); } int ami_scsi_cmd(struct scsi_xfer *xs) { struct scsi_link *link = xs->sc_link; struct ami_softc *sc = link->adapter_softc; struct device *dev = link->device_softc; struct ami_ccb *ccb; struct ami_iocmd *cmd; struct scsi_inquiry_data inq; struct scsi_sense_data sd; struct scsi_read_cap_data rcd; u_int8_t target = link->target; u_int32_t blockno, blockcnt; struct scsi_rw *rw; struct scsi_rw_big *rwb; int error, flags; int s; AMI_DPRINTF(AMI_D_CMD, ("ami_scsi_cmd ")); s = splbio(); if (target >= sc->sc_nunits || !sc->sc_hdr[target].hd_present || link->lun != 0) { AMI_DPRINTF(AMI_D_CMD, ("no target %d ", target)); /* XXX should be XS_SENSE and sense filled out */ xs->error = XS_DRIVER_STUFFUP; xs->flags |= ITSDONE; scsi_done(xs); splx(s); return (COMPLETE); } error = 0; xs->error = XS_NOERROR; switch (xs->cmd->opcode) { case TEST_UNIT_READY: /* save off sd? after autoconf */ if (!cold) /* XXX bogus */ strlcpy(sc->sc_hdr[target].dev, dev->dv_xname, sizeof(sc->sc_hdr[target].dev)); case START_STOP: #if 0 case VERIFY: #endif AMI_DPRINTF(AMI_D_CMD, ("opc %d tgt %d ", xs->cmd->opcode, target)); break; case REQUEST_SENSE: AMI_DPRINTF(AMI_D_CMD, ("REQUEST SENSE tgt %d ", target)); bzero(&sd, sizeof sd); sd.error_code = 0x70; sd.segment = 0; sd.flags = SKEY_NO_SENSE; *(u_int32_t*)sd.info = htole32(0); sd.extra_len = 0; ami_copy_internal_data(xs, &sd, sizeof sd); break; case INQUIRY: AMI_DPRINTF(AMI_D_CMD, ("INQUIRY tgt %d ", target)); bzero(&inq, sizeof inq); inq.device = T_DIRECT; inq.dev_qual2 = 0; inq.version = 2; inq.response_format = 2; inq.additional_length = 32; strlcpy(inq.vendor, "AMI ", sizeof inq.vendor); snprintf(inq.product, sizeof inq.product, "Host drive #%02d", target); strlcpy(inq.revision, " ", sizeof inq.revision); ami_copy_internal_data(xs, &inq, sizeof inq); break; case READ_CAPACITY: AMI_DPRINTF(AMI_D_CMD, ("READ CAPACITY tgt %d ", target)); bzero(&rcd, sizeof rcd); _lto4b(sc->sc_hdr[target].hd_size - 1, rcd.addr); _lto4b(AMI_SECTOR_SIZE, rcd.length); ami_copy_internal_data(xs, &rcd, sizeof rcd); break; case PREVENT_ALLOW: AMI_DPRINTF(AMI_D_CMD, ("PREVENT/ALLOW ")); splx(s); return (COMPLETE); case SYNCHRONIZE_CACHE: AMI_DPRINTF(AMI_D_CMD, ("SYNCHRONIZE CACHE ")); error++; case READ_COMMAND: if (!error) { AMI_DPRINTF(AMI_D_CMD, ("READ ")); error++; } case READ_BIG: if (!error) { AMI_DPRINTF(AMI_D_CMD, ("READ BIG ")); error++; } case WRITE_COMMAND: if (!error) { AMI_DPRINTF(AMI_D_CMD, ("WRITE ")); error++; } case WRITE_BIG: if (!error) { AMI_DPRINTF(AMI_D_CMD, ("WRITE BIG ")); error++; } flags = xs->flags; if (xs->cmd->opcode != SYNCHRONIZE_CACHE) { /* A read or write operation. */ if (xs->cmdlen == 6) { rw = (struct scsi_rw *)xs->cmd; blockno = _3btol(rw->addr) & (SRW_TOPADDR << 16 | 0xffff); blockcnt = rw->length ? rw->length : 0x100; } else { rwb = (struct scsi_rw_big *)xs->cmd; blockno = _4btol(rwb->addr); blockcnt = _2btol(rwb->length); /* TODO: reflect DPO & FUA flags */ if (xs->cmd->opcode == WRITE_BIG && rwb->byte2 & 0x18) flags |= 0; } if (blockno >= sc->sc_hdr[target].hd_size || blockno + blockcnt > sc->sc_hdr[target].hd_size) { printf("%s: out of bounds %u-%u >= %u\n", sc->sc_dev.dv_xname, blockno, blockcnt, sc->sc_hdr[target].hd_size); xs->error = XS_DRIVER_STUFFUP; scsi_done(xs); splx(s); return (COMPLETE); } } if ((ccb = ami_get_ccb(sc)) == NULL) { AMI_DPRINTF(AMI_D_CMD, ("no more ccbs ")); xs->error = XS_DRIVER_STUFFUP; scsi_done(xs); splx(s); __asm __volatile(".globl _bpamiccb\n_bpamiccb:"); return (COMPLETE); } ccb->ccb_xs = xs; ccb->ccb_len = xs->datalen; ccb->ccb_dir = (xs->flags & SCSI_DATA_IN) ? AMI_CCB_IN : AMI_CCB_OUT; ccb->ccb_data = xs->data; cmd = &ccb->ccb_cmd; cmd->acc_mbox.amb_nsect = htole16(blockcnt); cmd->acc_mbox.amb_lba = htole32(blockno); cmd->acc_mbox.amb_ldn = target; cmd->acc_mbox.amb_data = 0; switch (xs->cmd->opcode) { case SYNCHRONIZE_CACHE: cmd->acc_cmd = AMI_FLUSH; if (xs->timeout < 30000) xs->timeout = 30000; /* at least 30sec */ break; case READ_COMMAND: case READ_BIG: cmd->acc_cmd = AMI_READ; break; case WRITE_COMMAND: case WRITE_BIG: cmd->acc_cmd = AMI_WRITE; break; } if ((error = ami_cmd(ccb, ((flags & SCSI_NOSLEEP)? BUS_DMA_NOWAIT : BUS_DMA_WAITOK), flags & SCSI_POLL))) { AMI_DPRINTF(AMI_D_CMD, ("failed %p ", xs)); __asm __volatile(".globl _bpamifail\n_bpamifail:"); if (flags & SCSI_POLL) { splx(s); return (TRY_AGAIN_LATER); } else { xs->error = XS_DRIVER_STUFFUP; scsi_done(xs); splx(s); return (COMPLETE); } } splx(s); if (flags & SCSI_POLL) return (COMPLETE); else return (SUCCESSFULLY_QUEUED); default: AMI_DPRINTF(AMI_D_CMD, ("unsupported scsi command %#x tgt %d ", xs->cmd->opcode, target)); xs->error = XS_DRIVER_STUFFUP; } splx(s); return (COMPLETE); } int ami_intr(void *v) { struct ami_softc *sc = v; struct ami_iocmd mbox; int i, rv = 0; int s; if (TAILQ_EMPTY(&sc->sc_ccbq)) return (0); AMI_DPRINTF(AMI_D_INTR, ("intr ")); s = splbio(); while ((sc->sc_done)(sc, &mbox)) { AMI_DPRINTF(AMI_D_CMD, ("got#%d ", mbox.acc_nstat)); for (i = 0; i < mbox.acc_nstat; i++ ) { int ready = mbox.acc_cmplidl[i]; AMI_DPRINTF(AMI_D_CMD, ("ready=%d ", ready)); if (!ami_done(sc, ready)) rv |= 1; } } #ifdef AMI_POLLING if (!TAILQ_EMPTY(&sc->sc_ccbq) && !timeout_pending(&sc->sc_poll_tmo)) { AMI_DPRINTF(AMI_D_INTR, ("tmo ")); timeout_add(&sc->sc_poll_tmo, 2); } #endif splx(s); AMI_DPRINTF(AMI_D_INTR, ("exit ")); return (rv); } int ami_scsi_ioctl(struct scsi_link *link, u_long cmd, caddr_t addr, int flag, struct proc *p) { struct ami_softc *sc = (struct ami_softc *)link->adapter_softc; /* struct device *dev = (struct device *)link->device_softc; */ /* u_int8_t target = link->target; */ if (sc->sc_ioctl) return (sc->sc_ioctl(link->adapter_softc, cmd, addr)); else return (ENOTTY); } #if NBIO > 0 int ami_ioctl(struct device *dev, u_long cmd, caddr_t addr) { struct ami_softc *sc = (struct ami_softc *)dev; int s; int error = 0; AMI_DPRINTF(AMI_D_IOCTL, ("%s: ioctl ", sc->sc_dev.dv_xname)); if (sc->sc_flags & AMI_BROKEN) return (ENODEV); /* can't do this to broken device for now */ s = splbio(); if (sc->sc_flags & AMI_CMDWAIT) { splx(s); return (EBUSY); } sc->sc_flags |= AMI_CMDWAIT; switch (cmd) { case BIOCINQ: AMI_DPRINTF(AMI_D_IOCTL, ("inq ")); error = ami_ioctl_inq(sc, (struct bioc_inq *)addr); break; case BIOCVOL: AMI_DPRINTF(AMI_D_IOCTL, ("vol ")); error = ami_ioctl_vol(sc, (struct bioc_vol *)addr); break; case BIOCDISK: AMI_DPRINTF(AMI_D_IOCTL, ("disk ")); error = ami_ioctl_disk(sc, (struct bioc_disk *)addr); break; case BIOCALARM: AMI_DPRINTF(AMI_D_IOCTL, ("alarm ")); error = ami_ioctl_alarm(sc, (struct bioc_alarm *)addr); break; case BIOCSETSTATE: AMI_DPRINTF(AMI_D_IOCTL, ("setstate ")); error = ami_ioctl_setstate(sc, (struct bioc_setstate *)addr); break; default: AMI_DPRINTF(AMI_D_IOCTL, ("%s: invalid ioctl\n", sc->sc_dev.dv_xname)); error = EINVAL; } sc->sc_flags &= ~AMI_CMDWAIT; splx(s); return (error); } int ami_drv_inq(struct ami_softc *sc, u_int8_t ch, u_int8_t tg, u_int8_t page, void *inqbuf) { struct ami_ccb *ccb; struct ami_passthrough *pt; struct scsi_inquiry_data *inq = inqbuf; ccb = ami_get_ccb(sc); if (ccb == NULL) return (ENOMEM); ccb->ccb_wakeup = 1; ccb->ccb_data = inqbuf; ccb->ccb_len = sizeof(struct scsi_inquiry_data); ccb->ccb_dir = AMI_CCB_IN; ccb->ccb_cmd.acc_cmd = AMI_PASSTHRU; pt = ccb->ccb_pt; memset(pt, 0, sizeof(struct ami_passthrough)); pt->apt_channel = ch; pt->apt_target = tg; pt->apt_ncdb = sizeof(struct scsi_inquiry); pt->apt_nsense = sizeof(struct scsi_sense_data); pt->apt_datalen = sizeof(struct scsi_inquiry_data); pt->apt_cdb[0] = INQUIRY; pt->apt_cdb[1] = 0; pt->apt_cdb[2] = 0; pt->apt_cdb[3] = 0; pt->apt_cdb[4] = sizeof(struct scsi_inquiry_data); /* INQUIRY length */ pt->apt_cdb[5] = 0; if (page != 0) { pt->apt_cdb[1] = SI_EVPD; pt->apt_cdb[2] = page; } if (ami_cmd(ccb, BUS_DMA_WAITOK, 0) != 0) return (EIO); while (ccb->ccb_wakeup) tsleep(ccb, PRIBIO, "ami_drv_inq", 0); ami_put_ccb(ccb); if (pt->apt_scsistat != 0x00) return (EIO); if ((inq->device & SID_TYPE) != T_DIRECT) return (EINVAL); return (0); } int ami_mgmt(struct ami_softc *sc, u_int8_t opcode, u_int8_t par1, u_int8_t par2, u_int8_t par3, size_t size, void *buffer) { struct ami_ccb *ccb; struct ami_iocmd *cmd; struct ami_mem *am; char *idata; int error = 0; ccb = ami_get_ccb(sc); if (ccb == NULL) return (ENOMEM); if ((am = ami_allocmem(sc, size)) == NULL) { ami_put_ccb(ccb); return (ENOMEM); } idata = AMIMEM_KVA(am); ccb->ccb_data = NULL; ccb->ccb_wakeup = 1; cmd = &ccb->ccb_cmd; cmd->acc_cmd = opcode; /* * some commands require data to be written to idata before sending * command to fw */ switch (opcode) { case AMI_SPEAKER: *idata = par1; break; default: cmd->acc_io.aio_channel = par1; cmd->acc_io.aio_param = par2; cmd->acc_io.aio_pad[0] = par3; break; }; cmd->acc_io.aio_data = htole32(AMIMEM_DVA(am)); if (ami_cmd(ccb, BUS_DMA_WAITOK, 0) == 0) { while (ccb->ccb_wakeup) tsleep(ccb, PRIBIO,"ami_mgmt", 0); ami_put_ccb(ccb); /* XXX how do commands fail? */ if (buffer) memcpy(buffer, idata, size); } else error = EINVAL; ami_freemem(sc, am); return (error); } int ami_ioctl_inq(struct ami_softc *sc, struct bioc_inq *bi) { struct ami_big_diskarray *p; /* struct too large for stack */ char *plist; int i, s, t; int off; int error = 0; struct scsi_inquiry_data inqbuf; u_int8_t ch, tg; p = malloc(sizeof *p, M_DEVBUF, M_NOWAIT); if (!p) { printf("%s: no memory for disk array\n",sc->sc_dev.dv_xname); return (ENOMEM); } plist = malloc(AMI_BIG_MAX_PDRIVES, M_DEVBUF, M_NOWAIT); if (!plist) { printf("%s: no memory for disk list\n",sc->sc_dev.dv_xname); error = ENOMEM; goto bail; } if (ami_mgmt(sc, AMI_FCOP, AMI_FC_RDCONF, 0, 0, sizeof *p, p)) { error = EINVAL; goto bail2; } memset(plist, 0, AMI_BIG_MAX_PDRIVES); bi->bi_novol = p->ada_nld; bi->bi_nodisk = 0; strlcpy(bi->bi_dev, sc->sc_dev.dv_xname, sizeof(bi->bi_dev)); /* do we actually care how many disks we have at this point? */ for (i = 0; i < p->ada_nld; i++) for (s = 0; s < p->ald[i].adl_spandepth; s++) for (t = 0; t < p->ald[i].adl_nstripes; t++) { off = p->ald[i].asp[s].adv[t].add_channel * AMI_MAX_TARGET + p->ald[i].asp[s].adv[t].add_target; if (!plist[off]) { plist[off] = 1; bi->bi_nodisk++; } } /* * hack warning! * Megaraid cards sometimes return a size in the PD structure * even though there is no disk in that slot. Work around * that by issuing an INQUIRY to determine if there is * an actual disk in the slot. */ for(i = 0; i < ((sc->sc_flags & AMI_QUARTZ) ? AMI_BIG_MAX_PDRIVES : AMI_MAX_PDRIVES); i++) { /* skip claimed drives */ if (plist[i]) continue; /* * poke drive to make sure its there. If it is it is either * unused or a hot spare; at this point we dont care which it is */ if (p->apd[i].adp_size) { ch = (i & 0xf0) >> 4; tg = i & 0x0f; if (!ami_drv_inq(sc, ch, tg, 0, &inqbuf)) { bi->bi_novol++; bi->bi_nodisk++; plist[i] = 1; } } } bail2: free(plist, M_DEVBUF); bail: free(p, M_DEVBUF); return (error); } int ami_vol(struct ami_softc *sc, struct bioc_vol *bv, struct ami_big_diskarray *p) { struct scsi_inquiry_data inqbuf; char *plist; int i, s, t, off; int ld = p->ada_nld, error = EINVAL; u_int8_t ch, tg; plist = malloc(AMI_BIG_MAX_PDRIVES, M_DEVBUF, M_NOWAIT); if (!plist) { printf("%s: no memory for disk list\n",sc->sc_dev.dv_xname); return (ENOMEM); } memset(plist, 0, AMI_BIG_MAX_PDRIVES); /* setup plist */ for (i = 0; i < p->ada_nld; i++) for (s = 0; s < p->ald[i].adl_spandepth; s++) for (t = 0; t < p->ald[i].adl_nstripes; t++) { off = p->ald[i].asp[s].adv[t].add_channel * AMI_MAX_TARGET + p->ald[i].asp[s].adv[t].add_target; if (!plist[off]) plist[off] = 1; } for(i = 0; i < ((sc->sc_flags & AMI_QUARTZ) ? AMI_BIG_MAX_PDRIVES : AMI_MAX_PDRIVES); i++) { /* skip claimed drives */ if (plist[i]) continue; /* * poke drive to make sure its there. If it is it is either * unused or a hot spare; at this point we dont care which it is */ if (p->apd[i].adp_size) { ch = (i & 0xf0) >> 4; tg = i & 0x0f; if (!ami_drv_inq(sc, ch, tg, 0, &inqbuf)) { if (ld != bv->bv_volid) { ld++; continue; } bv->bv_status = BIOC_SVONLINE; bv->bv_size = (u_quad_t)p->apd[i].adp_size * (u_quad_t)512; bv->bv_nodisk = 1; strlcpy(bv->bv_dev, sc->sc_hdr[bv->bv_volid].dev, sizeof(bv->bv_dev)); if (p->apd[i].adp_ostatus == AMI_PD_HOTSPARE && p->apd[i].adp_type == 0) bv->bv_level = -1; else bv->bv_level = -2; error = 0; goto bail; } } } bail: free(plist, M_DEVBUF); return (error); } int ami_disk(struct ami_softc *sc, struct bioc_disk *bd, struct ami_big_diskarray *p) { struct scsi_inquiry_data inqbuf; struct scsi_inquiry_vpd vpdbuf; char *plist; int i, s, t, off; int ld = p->ada_nld, error = EINVAL; u_int8_t ch, tg; plist = malloc(AMI_BIG_MAX_PDRIVES, M_DEVBUF, M_NOWAIT); if (!plist) { printf("%s: no memory for disk list\n",sc->sc_dev.dv_xname); return (ENOMEM); } memset(plist, 0, AMI_BIG_MAX_PDRIVES); /* setup plist */ for (i = 0; i < p->ada_nld; i++) for (s = 0; s < p->ald[i].adl_spandepth; s++) for (t = 0; t < p->ald[i].adl_nstripes; t++) { off = p->ald[i].asp[s].adv[t].add_channel * AMI_MAX_TARGET + p->ald[i].asp[s].adv[t].add_target; if (!plist[off]) plist[off] = 1; } for(i = 0; i < ((sc->sc_flags & AMI_QUARTZ) ? AMI_BIG_MAX_PDRIVES : AMI_MAX_PDRIVES); i++) { /* skip claimed drives */ if (plist[i]) continue; /* * poke drive to make sure its there. If it is it is either * unused or a hot spare; at this point we dont care which it is */ if (p->apd[i].adp_size) { ch = (i & 0xf0) >> 4; tg = i & 0x0f; if (!ami_drv_inq(sc, ch, tg, 0, &inqbuf)) { char vend[8+16+4+1]; if (ld != bd->bd_volid) { ld++; continue; } bcopy(inqbuf.vendor, vend, sizeof vend - 1); vend[sizeof vend - 1] = '\0'; strlcpy(bd->bd_vendor, vend, sizeof(bd->bd_vendor)); if (!ami_drv_inq(sc, ch, tg, 0x80, &vpdbuf)) { char ser[32 + 1]; bcopy(vpdbuf.serial, ser, sizeof ser - 1); ser[sizeof ser - 1] = '\0'; if (vpdbuf.page_length < sizeof ser) ser[vpdbuf.page_length] = '\0'; strlcpy(bd->bd_serial, ser, sizeof(bd->bd_serial)); } bd->bd_size = (u_quad_t)p->apd[i].adp_size * (u_quad_t)512; bd->bd_channel = ch; bd->bd_target = tg; strlcpy(bd->bd_procdev, sc->sc_rawsoftcs[ch].sc_procdev, sizeof(bd->bd_procdev)); if (p->apd[i].adp_ostatus == AMI_PD_HOTSPARE && p->apd[i].adp_type == 0) bd->bd_status = BIOC_SDHOTSPARE; else bd->bd_status = BIOC_SDUNUSED; error = 0; goto bail; } } } bail: free(plist, M_DEVBUF); return (error); } int ami_ioctl_vol(struct ami_softc *sc, struct bioc_vol *bv) { struct ami_big_diskarray *p; /* struct too large for stack */ int i, s, t; int error = 0; p = malloc(sizeof *p, M_DEVBUF, M_NOWAIT); if (!p) { printf("%s: no memory for raw interface\n",sc->sc_dev.dv_xname); return (ENOMEM); } if (ami_mgmt(sc, AMI_FCOP, AMI_FC_RDCONF, 0, 0, sizeof *p, p)) { error = EINVAL; goto bail; } if (bv->bv_volid >= p->ada_nld) { error = ami_vol(sc, bv, p); goto bail; } i = bv->bv_volid; switch (p->ald[i].adl_status) { case AMI_RDRV_OFFLINE: bv->bv_status = BIOC_SVOFFLINE; break; case AMI_RDRV_DEGRADED: bv->bv_status = BIOC_SVDEGRADED; break; case AMI_RDRV_OPTIMAL: bv->bv_status = BIOC_SVONLINE; break; default: bv->bv_status = BIOC_SVINVALID; } bv->bv_size = 0; bv->bv_level = p->ald[i].adl_raidlvl; bv->bv_nodisk = 0; for (s = 0; s < p->ald[i].adl_spandepth; s++) { for (t = 0; t < p->ald[i].adl_nstripes; t++) bv->bv_nodisk++; switch (bv->bv_level) { case 0: bv->bv_size += p->ald[i].asp[s].ads_length * p->ald[i].adl_nstripes; break; case 1: bv->bv_size += p->ald[i].asp[s].ads_length; break; case 5: bv->bv_size += p->ald[i].asp[s].ads_length * (p->ald[i].adl_nstripes - 1); break; } } if (p->ald[i].adl_spandepth > 1) bv->bv_level *= 10; bv->bv_size *= (u_quad_t)512; strlcpy(bv->bv_dev, sc->sc_hdr[i].dev, sizeof(bv->bv_dev)); bail: free(p, M_DEVBUF); return (error); } int ami_ioctl_disk(struct ami_softc *sc, struct bioc_disk *bd) { struct scsi_inquiry_data inqbuf; struct scsi_inquiry_vpd vpdbuf; struct ami_big_diskarray *p; /* struct too large for stack */ int i, s, t, d; int off; int error = 0; u_int16_t ch, tg; p = malloc(sizeof *p, M_DEVBUF, M_NOWAIT); if (!p) { printf("%s: no memory for raw interface\n",sc->sc_dev.dv_xname); return (ENOMEM); } if (ami_mgmt(sc, AMI_FCOP, AMI_FC_RDCONF, 0, 0, sizeof *p, p)) { error = EINVAL; goto bail; } if (bd->bd_volid >= p->ada_nld) { error = ami_disk(sc, bd, p); goto bail; } i = bd->bd_volid; error = EINVAL; for (s = 0, d = 0; s < p->ald[i].adl_spandepth; s++) for (t = 0; t < p->ald[i].adl_nstripes; t++) { if (d != bd->bd_diskid) { d++; continue; } off = p->ald[i].asp[s].adv[t].add_channel * AMI_MAX_TARGET + p->ald[i].asp[s].adv[t].add_target; switch (p->apd[off].adp_ostatus) { case AMI_PD_UNCNF: bd->bd_status = BIOC_SDUNUSED; break; case AMI_PD_ONLINE: bd->bd_status = BIOC_SDONLINE; break; case AMI_PD_FAILED: bd->bd_status = BIOC_SDFAILED; break; case AMI_PD_RBLD: bd->bd_status = BIOC_SDREBUILD; break; case AMI_PD_HOTSPARE: bd->bd_status = BIOC_SDHOTSPARE; break; default: bd->bd_status = BIOC_SDINVALID; } bd->bd_size = (u_quad_t)p->apd[off].adp_size * (u_quad_t)512; ch = p->ald[i].asp[s].adv[t].add_target >> 4; tg = p->ald[i].asp[s].adv[t].add_target & 0x0f; if (!ami_drv_inq(sc, ch, tg, 0, &inqbuf)) { char vend[8+16+4+1]; bcopy(inqbuf.vendor, vend, sizeof vend - 1); vend[sizeof vend - 1] = '\0'; strlcpy(bd->bd_vendor, vend, sizeof(bd->bd_vendor)); } if (!ami_drv_inq(sc, ch, tg, 0x80, &vpdbuf)) { char ser[32 + 1]; bcopy(vpdbuf.serial, ser, sizeof ser - 1); ser[sizeof ser - 1] = '\0'; if (vpdbuf.page_length < sizeof ser) ser[vpdbuf.page_length] = '\0'; strlcpy(bd->bd_serial, ser, sizeof(bd->bd_serial)); } bd->bd_channel = ch; bd->bd_target = tg; strlcpy(bd->bd_procdev, sc->sc_rawsoftcs[ch].sc_procdev, sizeof(bd->bd_procdev)); error = 0; goto bail; } /* XXX if we reach this do dedicated hotspare magic*/ bail: free(p, M_DEVBUF); return (error); } int ami_ioctl_alarm(struct ami_softc *sc, struct bioc_alarm *ba) { int error = 0; u_int8_t func, ret; switch(ba->ba_opcode) { case BIOC_SADISABLE: func = AMI_SPKR_OFF; break; case BIOC_SAENABLE: func = AMI_SPKR_ON; break; case BIOC_SASILENCE: func = AMI_SPKR_SHUT; break; case BIOC_GASTATUS: func = AMI_SPKR_GVAL; break; case BIOC_SATEST: func = AMI_SPKR_TEST; break; default: AMI_DPRINTF(AMI_D_IOCTL, ("%s: biocalarm invalid opcode %x\n", sc->sc_dev.dv_xname, ba->ba_opcode)); return (EINVAL); } if (ami_mgmt(sc, AMI_SPEAKER, func, 0, 0, sizeof ret, &ret)) error = EINVAL; else if (ba->ba_opcode == BIOC_GASTATUS) ba->ba_status = ret; else ba->ba_status = 0; return (error); } int ami_ioctl_setstate(struct ami_softc *sc, struct bioc_setstate *bs) { int func; struct ami_big_diskarray *p; struct scsi_inquiry_data inqbuf; int off; switch (bs->bs_status) { case BIOC_SSONLINE: func = AMI_STATE_ON; break; case BIOC_SSOFFLINE: func = AMI_STATE_FAIL; break; case BIOC_SSHOTSPARE: p = malloc(sizeof *p, M_DEVBUF, M_NOWAIT); if (!p) { printf("%s: no memory for setstate\n", sc->sc_dev.dv_xname); return (ENOMEM); } if (ami_mgmt(sc, AMI_FCOP, AMI_FC_RDCONF, 0, 0, sizeof *p, p)) goto bail; off = bs->bs_channel * AMI_MAX_TARGET + bs->bs_target; if (ami_drv_inq(sc, bs->bs_channel, bs->bs_target, 0, &inqbuf)) goto bail; free(p, M_DEVBUF); func = AMI_STATE_SPARE; break; default: AMI_DPRINTF(AMI_D_IOCTL, ("%s: biocsetstate invalid opcode %x\n" , sc->sc_dev.dv_xname, bs->bs_status)); return (EINVAL); } if (ami_mgmt(sc, AMI_CHSTATE, bs->bs_channel, bs->bs_target, func, 0, NULL)) return (EINVAL); return (0); bail: free(p, M_DEVBUF); return (EINVAL); } #endif /* NBIO > 0 */ #ifdef AMI_DEBUG void ami_print_mbox(struct ami_iocmd *mbox) { int i; printf("acc_cmd: %d aac_id: %d acc_busy: %d acc_nstat: %d", mbox->acc_cmd, mbox->acc_id, mbox->acc_busy, mbox->acc_nstat); printf("acc_status: %d acc_poll: %d acc_ack: %d\n", mbox->acc_status, mbox->acc_poll, mbox->acc_ack); printf("acc_cmplidl: "); for (i = 0; i < AMI_MAXSTATACK; i++) { printf("[%d] = %d ", i, mbox->acc_cmplidl[i]); } printf("\n"); } #endif /* AMI_DEBUG */