/* $OpenBSD: gdt_common.c,v 1.29 2005/07/03 22:31:27 krw Exp $ */ /* * Copyright (c) 1999, 2000, 2003 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 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. */ /* * This driver would not have written if it was not for the hardware donations * from both ICP-Vortex and Öko.neT. I want to thank them for their support. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "bio.h" #ifdef GDT_DEBUG int gdt_maxcmds = GDT_MAXCMDS; #undef GDT_MAXCMDS #define GDT_MAXCMDS gdt_maxcmds #endif #define GDT_DRIVER_VERSION 1 #define GDT_DRIVER_SUBVERSION 2 int gdt_async_event(struct gdt_softc *, int); void gdt_chain(struct gdt_softc *); void gdt_clear_events(struct gdt_softc *); void gdt_copy_internal_data(struct scsi_xfer *, u_int8_t *, size_t); struct scsi_xfer *gdt_dequeue(struct gdt_softc *); void gdt_enqueue(struct gdt_softc *, struct scsi_xfer *, int); void gdt_enqueue_ccb(struct gdt_softc *, struct gdt_ccb *); void gdt_eval_mapping(u_int32_t, int *, int *, int *); int gdt_exec_ccb(struct gdt_ccb *); void gdt_free_ccb(struct gdt_softc *, struct gdt_ccb *); struct gdt_ccb *gdt_get_ccb(struct gdt_softc *, int); int gdt_internal_cache_cmd(struct scsi_xfer *); int gdt_internal_cmd(struct gdt_softc *, u_int8_t, u_int16_t, u_int32_t, u_int32_t, u_int32_t); #if NBIO > 0 int gdt_ioctl(struct device *, u_long, caddr_t); #endif int gdt_raw_scsi_cmd(struct scsi_xfer *); int gdt_scsi_cmd(struct scsi_xfer *); void gdt_start_ccbs(struct gdt_softc *); int gdt_sync_event(struct gdt_softc *, int, u_int8_t, struct scsi_xfer *); void gdt_timeout(void *); int gdt_wait(struct gdt_softc *, struct gdt_ccb *, int); void gdt_watchdog(void *); struct cfdriver gdt_cd = { NULL, "gdt", DV_DULL }; struct scsi_adapter gdt_switch = { gdt_scsi_cmd, gdtminphys, 0, 0, }; struct scsi_adapter gdt_raw_switch = { gdt_raw_scsi_cmd, gdtminphys, 0, 0, }; struct scsi_device gdt_dev = { NULL, NULL, NULL, NULL }; int gdt_cnt = 0; u_int8_t gdt_polling; u_int8_t gdt_from_wait; struct gdt_softc *gdt_wait_gdt; int gdt_wait_index; #ifdef GDT_DEBUG int gdt_debug = GDT_DEBUG; #endif int gdt_attach(gdt) struct gdt_softc *gdt; { u_int16_t cdev_cnt; int i, id, drv_cyls, drv_hds, drv_secs, error, nsegs; gdt_polling = 1; gdt_from_wait = 0; if (bus_dmamem_alloc(gdt->sc_dmat, GDT_SCRATCH_SZ, PAGE_SIZE, 0, &gdt->sc_scratch_seg, 1, &nsegs, BUS_DMA_NOWAIT)) panic("%s: bus_dmamem_alloc failed", gdt->sc_dev.dv_xname); if (bus_dmamem_map(gdt->sc_dmat, &gdt->sc_scratch_seg, 1, GDT_SCRATCH_SZ, &gdt->sc_scratch, BUS_DMA_NOWAIT)) panic("%s: bus_dmamem_map failed", gdt->sc_dev.dv_xname); gdt_clear_events(gdt); TAILQ_INIT(&gdt->sc_free_ccb); TAILQ_INIT(&gdt->sc_ccbq); TAILQ_INIT(&gdt->sc_ucmdq); LIST_INIT(&gdt->sc_queue); /* Initialize the ccbs */ for (i = 0; i < GDT_MAXCMDS; i++) { gdt->sc_ccbs[i].gc_cmd_index = i + 2; error = bus_dmamap_create(gdt->sc_dmat, (GDT_MAXOFFSETS - 1) << PGSHIFT, GDT_MAXOFFSETS, (GDT_MAXOFFSETS - 1) << PGSHIFT, 0, BUS_DMA_NOWAIT | BUS_DMA_ALLOCNOW, &gdt->sc_ccbs[i].gc_dmamap_xfer); if (error) { printf("%s: cannot create ccb dmamap (%d)", gdt->sc_dev.dv_xname, error); return (1); } (void)gdt_ccb_set_cmd(gdt->sc_ccbs + i, GDT_GCF_UNUSED); TAILQ_INSERT_TAIL(&gdt->sc_free_ccb, &gdt->sc_ccbs[i], gc_chain); } /* Fill in the prototype scsi_link. */ gdt->sc_link.adapter_softc = gdt; gdt->sc_link.adapter = &gdt_switch; gdt->sc_link.device = &gdt_dev; /* openings will be filled in later. */ gdt->sc_link.adapter_buswidth = (gdt->sc_class & GDT_FC) ? GDT_MAXID : GDT_MAX_HDRIVES; gdt->sc_link.adapter_target = gdt->sc_link.adapter_buswidth; if (!gdt_internal_cmd(gdt, GDT_SCREENSERVICE, GDT_INIT, 0, 0, 0)) { printf("screen service initialization error %d\n", gdt->sc_status); return (1); } if (!gdt_internal_cmd(gdt, GDT_CACHESERVICE, GDT_INIT, GDT_LINUX_OS, 0, 0)) { printf("cache service initialization error %d\n", gdt->sc_status); return (1); } cdev_cnt = (u_int16_t)gdt->sc_info; /* Detect number of busses */ gdt_enc32(gdt->sc_scratch + GDT_IOC_VERSION, GDT_IOC_NEWEST); gdt->sc_scratch[GDT_IOC_LIST_ENTRIES] = GDT_MAXBUS; gdt->sc_scratch[GDT_IOC_FIRST_CHAN] = 0; gdt->sc_scratch[GDT_IOC_LAST_CHAN] = GDT_MAXBUS - 1; gdt_enc32(gdt->sc_scratch + GDT_IOC_LIST_OFFSET, GDT_IOC_HDR_SZ); if (gdt_internal_cmd(gdt, GDT_CACHESERVICE, GDT_IOCTL, GDT_IOCHAN_RAW_DESC, GDT_INVALID_CHANNEL, GDT_IOC_HDR_SZ + GDT_RAWIOC_SZ)) { gdt->sc_bus_cnt = gdt->sc_scratch[GDT_IOC_CHAN_COUNT]; for (i = 0; i < gdt->sc_bus_cnt; i++) { id = gdt->sc_scratch[GDT_IOC_HDR_SZ + i * GDT_RAWIOC_SZ + GDT_RAWIOC_PROC_ID]; gdt->sc_bus_id[id] = id < GDT_MAXBUS ? id : 0xff; } } else { /* New method failed, use fallback. */ gdt_enc32(gdt->sc_scratch + GDT_GETCH_CHANNEL_NO, i); for (i = 0; i < GDT_MAXBUS; i++) { if (!gdt_internal_cmd(gdt, GDT_CACHESERVICE, GDT_IOCTL, GDT_SCSI_CHAN_CNT | GDT_L_CTRL_PATTERN, GDT_IO_CHANNEL | GDT_INVALID_CHANNEL, GDT_GETCH_SZ)) { if (i == 0) { printf("cannot get channel count, " "error %d\n", gdt->sc_status); return (1); } break; } gdt->sc_bus_id[i] = (gdt->sc_scratch[GDT_GETCH_SIOP_ID] < GDT_MAXID) ? gdt->sc_scratch[GDT_GETCH_SIOP_ID] : 0xff; } gdt->sc_bus_cnt = i; } /* Read cache configuration */ if (!gdt_internal_cmd(gdt, GDT_CACHESERVICE, GDT_IOCTL, GDT_CACHE_INFO, GDT_INVALID_CHANNEL, GDT_CINFO_SZ)) { printf("cannot get cache info, error %d\n", gdt->sc_status); return (1); } gdt->sc_cpar.cp_version = gdt_dec32(gdt->sc_scratch + GDT_CPAR_VERSION); gdt->sc_cpar.cp_state = gdt_dec16(gdt->sc_scratch + GDT_CPAR_STATE); gdt->sc_cpar.cp_strategy = gdt_dec16(gdt->sc_scratch + GDT_CPAR_STRATEGY); gdt->sc_cpar.cp_write_back = gdt_dec16(gdt->sc_scratch + GDT_CPAR_WRITE_BACK); gdt->sc_cpar.cp_block_size = gdt_dec16(gdt->sc_scratch + GDT_CPAR_BLOCK_SIZE); /* Read board information and features */ gdt->sc_more_proc = 0; if (gdt_internal_cmd(gdt, GDT_CACHESERVICE, GDT_IOCTL, GDT_BOARD_INFO, GDT_INVALID_CHANNEL, GDT_BINFO_SZ)) { /* XXX A lot of these assignments can probably go later */ gdt->sc_binfo.bi_ser_no = gdt_dec32(gdt->sc_scratch + GDT_BINFO_SER_NO); bcopy(gdt->sc_scratch + GDT_BINFO_OEM_ID, gdt->sc_binfo.bi_oem_id, sizeof gdt->sc_binfo.bi_oem_id); gdt->sc_binfo.bi_ep_flags = gdt_dec16(gdt->sc_scratch + GDT_BINFO_EP_FLAGS); gdt->sc_binfo.bi_proc_id = gdt_dec32(gdt->sc_scratch + GDT_BINFO_PROC_ID); gdt->sc_binfo.bi_memsize = gdt_dec32(gdt->sc_scratch + GDT_BINFO_MEMSIZE); gdt->sc_binfo.bi_mem_banks = gdt->sc_scratch[GDT_BINFO_MEM_BANKS]; gdt->sc_binfo.bi_chan_type = gdt->sc_scratch[GDT_BINFO_CHAN_TYPE]; gdt->sc_binfo.bi_chan_count = gdt->sc_scratch[GDT_BINFO_CHAN_COUNT]; gdt->sc_binfo.bi_rdongle_pres = gdt->sc_scratch[GDT_BINFO_RDONGLE_PRES]; gdt->sc_binfo.bi_epr_fw_ver = gdt_dec32(gdt->sc_scratch + GDT_BINFO_EPR_FW_VER); gdt->sc_binfo.bi_upd_fw_ver = gdt_dec32(gdt->sc_scratch + GDT_BINFO_UPD_FW_VER); gdt->sc_binfo.bi_upd_revision = gdt_dec32(gdt->sc_scratch + GDT_BINFO_UPD_REVISION); bcopy(gdt->sc_scratch + GDT_BINFO_TYPE_STRING, gdt->sc_binfo.bi_type_string, sizeof gdt->sc_binfo.bi_type_string); bcopy(gdt->sc_scratch + GDT_BINFO_RAID_STRING, gdt->sc_binfo.bi_raid_string, sizeof gdt->sc_binfo.bi_raid_string); gdt->sc_binfo.bi_update_pres = gdt->sc_scratch[GDT_BINFO_UPDATE_PRES]; gdt->sc_binfo.bi_xor_pres = gdt->sc_scratch[GDT_BINFO_XOR_PRES]; gdt->sc_binfo.bi_prom_type = gdt->sc_scratch[GDT_BINFO_PROM_TYPE]; gdt->sc_binfo.bi_prom_count = gdt->sc_scratch[GDT_BINFO_PROM_COUNT]; gdt->sc_binfo.bi_dup_pres = gdt_dec32(gdt->sc_scratch + GDT_BINFO_DUP_PRES); gdt->sc_binfo.bi_chan_pres = gdt_dec32(gdt->sc_scratch + GDT_BINFO_CHAN_PRES); gdt->sc_binfo.bi_mem_pres = gdt_dec32(gdt->sc_scratch + GDT_BINFO_MEM_PRES); gdt->sc_binfo.bi_ft_bus_system = gdt->sc_scratch[GDT_BINFO_FT_BUS_SYSTEM]; gdt->sc_binfo.bi_subtype_valid = gdt->sc_scratch[GDT_BINFO_SUBTYPE_VALID]; gdt->sc_binfo.bi_board_subtype = gdt->sc_scratch[GDT_BINFO_BOARD_SUBTYPE]; gdt->sc_binfo.bi_rampar_pres = gdt->sc_scratch[GDT_BINFO_RAMPAR_PRES]; if (gdt_internal_cmd(gdt, GDT_CACHESERVICE, GDT_IOCTL, GDT_BOARD_FEATURES, GDT_INVALID_CHANNEL, GDT_BFEAT_SZ)) { gdt->sc_bfeat.bf_chaining = gdt->sc_scratch[GDT_BFEAT_CHAINING]; gdt->sc_bfeat.bf_striping = gdt->sc_scratch[GDT_BFEAT_STRIPING]; gdt->sc_bfeat.bf_mirroring = gdt->sc_scratch[GDT_BFEAT_MIRRORING]; gdt->sc_bfeat.bf_raid = gdt->sc_scratch[GDT_BFEAT_RAID]; gdt->sc_more_proc = 1; } } else { /* XXX Not implemented yet */ } /* Read more information */ if (gdt->sc_more_proc) { /* XXX Not implemented yet */ } if (!gdt_internal_cmd(gdt, GDT_SCSIRAWSERVICE, GDT_INIT, 0, 0, 0)) { printf("raw service initialization error %d\n", gdt->sc_status); return (1); } /* Set/get features raw service (scatter/gather) */ gdt->sc_raw_feat = 0; if (gdt_internal_cmd(gdt, GDT_SCSIRAWSERVICE, GDT_SET_FEAT, GDT_SCATTER_GATHER, 0, 0)) if (gdt_internal_cmd(gdt, GDT_SCSIRAWSERVICE, GDT_GET_FEAT, 0, 0, 0)) gdt->sc_raw_feat = gdt->sc_info; /* Set/get features cache service (scatter/gather) */ gdt->sc_cache_feat = 0; if (gdt_internal_cmd(gdt, GDT_CACHESERVICE, GDT_SET_FEAT, 0, GDT_SCATTER_GATHER, 0)) if (gdt_internal_cmd(gdt, GDT_CACHESERVICE, GDT_GET_FEAT, 0, 0, 0)) gdt->sc_cache_feat = gdt->sc_info; /* XXX Linux reserve drives here, potentially */ gdt->sc_ndevs = 0; /* Scan for cache devices */ for (i = 0; i < cdev_cnt && i < GDT_MAX_HDRIVES; i++) if (gdt_internal_cmd(gdt, GDT_CACHESERVICE, GDT_INFO, i, 0, 0)) { gdt->sc_hdr[i].hd_present = 1; gdt->sc_hdr[i].hd_size = gdt->sc_info; if (gdt->sc_hdr[i].hd_size > 0) gdt->sc_ndevs++; /* * Evaluate mapping (sectors per head, heads per cyl) */ gdt->sc_hdr[i].hd_size &= ~GDT_SECS32; if (gdt->sc_info2 == 0) gdt_eval_mapping(gdt->sc_hdr[i].hd_size, &drv_cyls, &drv_hds, &drv_secs); else { drv_hds = gdt->sc_info2 & 0xff; drv_secs = (gdt->sc_info2 >> 8) & 0xff; drv_cyls = gdt->sc_hdr[i].hd_size / drv_hds / drv_secs; } gdt->sc_hdr[i].hd_heads = drv_hds; gdt->sc_hdr[i].hd_secs = drv_secs; /* Round the size */ gdt->sc_hdr[i].hd_size = drv_cyls * drv_hds * drv_secs; if (gdt_internal_cmd(gdt, GDT_CACHESERVICE, GDT_DEVTYPE, i, 0, 0)) gdt->sc_hdr[i].hd_devtype = gdt->sc_info; } if (gdt->sc_ndevs == 0) gdt->sc_link.openings = 0; else gdt->sc_link.openings = (GDT_MAXCMDS - GDT_CMD_RESERVE) / gdt->sc_ndevs; printf("dpmem %x %d-bus %d cache device%s\n", gdt->sc_dpmembase, gdt->sc_bus_cnt, cdev_cnt, cdev_cnt == 1 ? "" : "s"); printf("%s: ver %x, cache %s, strategy %d, writeback %s, blksz %d\n", gdt->sc_dev.dv_xname, gdt->sc_cpar.cp_version, gdt->sc_cpar.cp_state ? "on" : "off", gdt->sc_cpar.cp_strategy, gdt->sc_cpar.cp_write_back ? "on" : "off", gdt->sc_cpar.cp_block_size); #if 1 printf("%s: raw feat %x cache feat %x\n", gdt->sc_dev.dv_xname, gdt->sc_raw_feat, gdt->sc_cache_feat); #endif #if NBIO > 0 if (bio_register(&gdt->sc_dev, gdt_ioctl) != 0) panic("%s: controller registration failed", gdt->sc_dev.dv_xname); #endif gdt_cnt++; config_found(&gdt->sc_dev, &gdt->sc_link, scsiprint); gdt->sc_raw_link = malloc(gdt->sc_bus_cnt * sizeof (struct scsi_link), M_DEVBUF, M_NOWAIT); if (gdt->sc_raw_link == NULL) panic("gdt_attach"); bzero(gdt->sc_raw_link, gdt->sc_bus_cnt * sizeof (struct scsi_link)); for (i = 0; i < gdt->sc_bus_cnt; i++) { /* Fill in the prototype scsi_link. */ gdt->sc_raw_link[i].adapter_softc = gdt; gdt->sc_raw_link[i].adapter = &gdt_raw_switch; gdt->sc_raw_link[i].adapter_target = 7; gdt->sc_raw_link[i].device = &gdt_dev; gdt->sc_raw_link[i].openings = 4; /* XXX a guess */ gdt->sc_raw_link[i].adapter_buswidth = (gdt->sc_class & GDT_FC) ? GDT_MAXID : 16; /* XXX */ config_found(&gdt->sc_dev, &gdt->sc_raw_link[i], scsiprint); } gdt_polling = 0; return (0); } void gdt_eval_mapping(size, cyls, heads, secs) u_int32_t size; int *cyls, *heads, *secs; { *cyls = size / GDT_HEADS / GDT_SECS; if (*cyls < GDT_MAXCYLS) { *heads = GDT_HEADS; *secs = GDT_SECS; } else { /* Too high for 64 * 32 */ *cyls = size / GDT_MEDHEADS / GDT_MEDSECS; if (*cyls < GDT_MAXCYLS) { *heads = GDT_MEDHEADS; *secs = GDT_MEDSECS; } else { /* Too high for 127 * 63 */ *cyls = size / GDT_BIGHEADS / GDT_BIGSECS; *heads = GDT_BIGHEADS; *secs = GDT_BIGSECS; } } } /* * Insert a command into the driver queue, either at the front or at the tail. * It's ok to overload the freelist link as these structures are never on * the freelist at this time. */ void gdt_enqueue(gdt, xs, infront) struct gdt_softc *gdt; struct scsi_xfer *xs; int infront; { if (infront || LIST_FIRST(&gdt->sc_queue) == NULL) { if (LIST_FIRST(&gdt->sc_queue) == NULL) gdt->sc_queuelast = xs; LIST_INSERT_HEAD(&gdt->sc_queue, xs, free_list); return; } LIST_INSERT_AFTER(gdt->sc_queuelast, xs, free_list); gdt->sc_queuelast = xs; } /* * Pull a command off the front of the driver queue. */ struct scsi_xfer * gdt_dequeue(gdt) struct gdt_softc *gdt; { struct scsi_xfer *xs; xs = LIST_FIRST(&gdt->sc_queue); if (xs == NULL) return (NULL); LIST_REMOVE(xs, free_list); if (LIST_FIRST(&gdt->sc_queue) == NULL) gdt->sc_queuelast = NULL; return (xs); } /* * Start a SCSI operation on a cache device. * XXX Polled operation is not yet complete. What kind of locking do we need? */ int gdt_scsi_cmd(xs) struct scsi_xfer *xs; { struct scsi_link *link = xs->sc_link; struct gdt_softc *gdt = link->adapter_softc; u_int8_t target = link->target; struct gdt_ccb *ccb; #if 0 struct gdt_ucmd *ucmd; #endif u_int32_t blockno, blockcnt; struct scsi_rw *rw; struct scsi_rw_big *rwb; bus_dmamap_t xfer; int error, retval = SUCCESSFULLY_QUEUED; gdt_lock_t lock; GDT_DPRINTF(GDT_D_CMD, ("gdt_scsi_cmd ")); xs->error = XS_NOERROR; if (target >= GDT_MAX_HDRIVES || !gdt->sc_hdr[target].hd_present || link->lun != 0) { /* * XXX Should be XS_SENSE but that would require setting up a * faked sense too. */ xs->error = XS_DRIVER_STUFFUP; xs->flags |= ITSDONE; scsi_done(xs); return (COMPLETE); } lock = GDT_LOCK_GDT(lock); /* Don't double enqueue if we came from gdt_chain. */ if (xs != LIST_FIRST(&gdt->sc_queue)) gdt_enqueue(gdt, xs, 0); while ((xs = gdt_dequeue(gdt)) != NULL) { xs->error = XS_NOERROR; ccb = NULL; link = xs->sc_link; target = link->target; if (!gdt_polling && !(xs->flags & SCSI_POLL) && gdt->sc_test_busy(gdt)) { /* * Put it back in front. XXX Should we instead * set xs->error to XS_BUSY? */ gdt_enqueue(gdt, xs, 1); break; } switch (xs->cmd->opcode) { case TEST_UNIT_READY: case REQUEST_SENSE: case INQUIRY: case MODE_SENSE: case START_STOP: case READ_CAPACITY: #if 0 case VERIFY: #endif if (!gdt_internal_cache_cmd(xs)) { GDT_UNLOCK_GDT(gdt, lock); return (TRY_AGAIN_LATER); } xs->flags |= ITSDONE; scsi_done(xs); goto ready; case PREVENT_ALLOW: GDT_DPRINTF(GDT_D_CMD, ("PREVENT/ALLOW ")); /* XXX Not yet implemented */ xs->error = XS_NOERROR; xs->flags |= ITSDONE; scsi_done(xs); goto ready; default: GDT_DPRINTF(GDT_D_CMD, ("unknown opc %d ", xs->cmd->opcode)); /* XXX Not yet implemented */ xs->error = XS_DRIVER_STUFFUP; xs->flags |= ITSDONE; scsi_done(xs); goto ready; case READ_COMMAND: case READ_BIG: case WRITE_COMMAND: case WRITE_BIG: case SYNCHRONIZE_CACHE: /* * A new command chain, start from the beginning. */ gdt->sc_cmd_off = 0; 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); } if (blockno >= gdt->sc_hdr[target].hd_size || blockno + blockcnt > gdt->sc_hdr[target].hd_size) { printf( "%s: out of bounds %u-%u >= %u\n", gdt->sc_dev.dv_xname, blockno, blockcnt, gdt->sc_hdr[target].hd_size); /* * XXX Should be XS_SENSE but that * would require setting up a faked * sense too. */ xs->error = XS_DRIVER_STUFFUP; xs->flags |= ITSDONE; scsi_done(xs); goto ready; } } ccb = gdt_get_ccb(gdt, xs->flags); /* * We are out of commands, try again in a little while. */ if (ccb == NULL) { xs->error = XS_DRIVER_STUFFUP; GDT_UNLOCK_GDT(gdt, lock); return (TRY_AGAIN_LATER); } ccb->gc_blockno = blockno; ccb->gc_blockcnt = blockcnt; ccb->gc_xs = xs; ccb->gc_timeout = xs->timeout; ccb->gc_service = GDT_CACHESERVICE; gdt_ccb_set_cmd(ccb, GDT_GCF_SCSI); if (xs->cmd->opcode != SYNCHRONIZE_CACHE) { xfer = ccb->gc_dmamap_xfer; error = bus_dmamap_load(gdt->sc_dmat, xfer, xs->data, xs->datalen, NULL, (xs->flags & SCSI_NOSLEEP) ? BUS_DMA_NOWAIT : BUS_DMA_WAITOK); if (error) { printf("%s: gdt_scsi_cmd: ", gdt->sc_dev.dv_xname); if (error == EFBIG) printf( "more than %d dma segs\n", GDT_MAXOFFSETS); else printf("error %d " "loading dma map\n", error); gdt_free_ccb(gdt, ccb); xs->error = XS_DRIVER_STUFFUP; xs->flags |= ITSDONE; scsi_done(xs); goto ready; } bus_dmamap_sync(gdt->sc_dmat, xfer, 0, xfer->dm_mapsize, (xs->flags & SCSI_DATA_IN) ? BUS_DMASYNC_PREREAD : BUS_DMASYNC_PREWRITE); } gdt_enqueue_ccb(gdt, ccb); /* XXX what if enqueue did not start a transfer? */ if (gdt_polling || (xs->flags & SCSI_POLL)) { if (!gdt_wait(gdt, ccb, ccb->gc_timeout)) { GDT_UNLOCK_GDT(gdt, lock); printf("%s: command %d timed out\n", gdt->sc_dev.dv_xname, ccb->gc_cmd_index); xs->error = XS_TIMEOUT; return (TRY_AGAIN_LATER); } xs->flags |= ITSDONE; scsi_done(xs); } } ready: /* * Don't process the queue if we are polling. */ if (xs->flags & SCSI_POLL) { retval = COMPLETE; break; } } GDT_UNLOCK_GDT(gdt, lock); return (retval); } /* XXX Currently only for cacheservice, returns 0 if busy */ int gdt_exec_ccb(ccb) struct gdt_ccb *ccb; { struct scsi_xfer *xs = ccb->gc_xs; struct scsi_link *link = xs->sc_link; struct gdt_softc *gdt = link->adapter_softc; u_int8_t target = link->target; u_int32_t sg_canz; bus_dmamap_t xfer; int i; #if 1 /* XXX */ static int __level = 0; if (__level++ > 0) panic("level > 0"); #endif GDT_DPRINTF(GDT_D_CMD, ("gdt_exec_ccb(%p, %p) ", xs, ccb)); gdt->sc_cmd_cnt = 0; /* * XXX Yeah I know it's an always-true condition, but that may change * later. */ if (gdt->sc_cmd_cnt == 0) gdt->sc_set_sema0(gdt); gdt_enc32(gdt->sc_cmd + GDT_CMD_COMMANDINDEX, ccb->gc_cmd_index); gdt_enc32(gdt->sc_cmd + GDT_CMD_BOARDNODE, GDT_LOCALBOARD); gdt_enc16(gdt->sc_cmd + GDT_CMD_UNION + GDT_CACHE_DEVICENO, target); switch (xs->cmd->opcode) { case PREVENT_ALLOW: case SYNCHRONIZE_CACHE: if (xs->cmd->opcode == PREVENT_ALLOW) { /* XXX PREVENT_ALLOW support goes here */ } else { GDT_DPRINTF(GDT_D_CMD, ("SYNCHRONIZE CACHE tgt %d ", target)); gdt->sc_cmd[GDT_CMD_OPCODE] = GDT_FLUSH; } gdt_enc32(gdt->sc_cmd + GDT_CMD_UNION + GDT_CACHE_BLOCKNO, 1); sg_canz = 0; break; case WRITE_COMMAND: case WRITE_BIG: /* XXX WRITE_THR could be supported too */ gdt->sc_cmd[GDT_CMD_OPCODE] = GDT_WRITE; break; case READ_COMMAND: case READ_BIG: gdt->sc_cmd[GDT_CMD_OPCODE] = GDT_READ; break; } if (xs->cmd->opcode != PREVENT_ALLOW && xs->cmd->opcode != SYNCHRONIZE_CACHE) { gdt_enc32(gdt->sc_cmd + GDT_CMD_UNION + GDT_CACHE_BLOCKNO, ccb->gc_blockno); gdt_enc32(gdt->sc_cmd + GDT_CMD_UNION + GDT_CACHE_BLOCKCNT, ccb->gc_blockcnt); xfer = ccb->gc_dmamap_xfer; if (gdt->sc_cache_feat & GDT_SCATTER_GATHER) { gdt_enc32( gdt->sc_cmd + GDT_CMD_UNION + GDT_CACHE_DESTADDR, 0xffffffff); for (i = 0; i < xfer->dm_nsegs; i++) { gdt_enc32(gdt->sc_cmd + GDT_CMD_UNION + GDT_CACHE_SG_LST + i * GDT_SG_SZ + GDT_SG_PTR, xfer->dm_segs[i].ds_addr); gdt_enc32(gdt->sc_cmd + GDT_CMD_UNION + GDT_CACHE_SG_LST + i * GDT_SG_SZ + GDT_SG_LEN, xfer->dm_segs[i].ds_len); GDT_DPRINTF(GDT_D_IO, ("#%d va %p pa %p len %x\n", i, buf, xfer->dm_segs[i].ds_addr, xfer->dm_segs[i].ds_len)); } sg_canz = xfer->dm_nsegs; gdt_enc32( gdt->sc_cmd + GDT_CMD_UNION + GDT_CACHE_SG_LST + sg_canz * GDT_SG_SZ + GDT_SG_LEN, 0); } else { /* XXX Hardly correct */ gdt_enc32( gdt->sc_cmd + GDT_CMD_UNION + GDT_CACHE_DESTADDR, xfer->dm_segs[0].ds_addr); sg_canz = 0; } } gdt_enc32(gdt->sc_cmd + GDT_CMD_UNION + GDT_CACHE_SG_CANZ, sg_canz); gdt->sc_cmd_len = roundup(GDT_CMD_UNION + GDT_CACHE_SG_LST + sg_canz * GDT_SG_SZ, sizeof (u_int32_t)); if (gdt->sc_cmd_cnt > 0 && gdt->sc_cmd_off + gdt->sc_cmd_len + GDT_DPMEM_COMMAND_OFFSET > gdt->sc_ic_all_size) { printf("%s: DPMEM overflow\n", gdt->sc_dev.dv_xname); gdt_free_ccb(gdt, ccb); xs->error = XS_BUSY; #if 1 /* XXX */ __level--; #endif return (0); } gdt->sc_copy_cmd(gdt, ccb); gdt->sc_release_event(gdt, ccb); xs->error = XS_NOERROR; xs->resid = 0; #if 1 /* XXX */ __level--; #endif return (1); } void gdt_copy_internal_data(xs, data, size) struct scsi_xfer *xs; u_int8_t *data; size_t size; { size_t copy_cnt; GDT_DPRINTF(GDT_D_MISC, ("gdt_copy_internal_data ")); if (!xs->datalen) printf("uio move not yet supported\n"); else { copy_cnt = MIN(size, xs->datalen); bcopy(data, xs->data, copy_cnt); } } /* Emulated SCSI operation on cache device */ int gdt_internal_cache_cmd(xs) struct scsi_xfer *xs; { struct scsi_link *link = xs->sc_link; struct gdt_softc *gdt = link->adapter_softc; struct scsi_inquiry_data inq; struct scsi_sense_data sd; struct { struct scsi_mode_header hd; struct scsi_blk_desc bd; union scsi_disk_pages dp; } mpd; struct scsi_read_cap_data rcd; u_int8_t target = link->target; GDT_DPRINTF(GDT_D_CMD, ("gdt_internal_cache_cmd ")); switch (xs->cmd->opcode) { case TEST_UNIT_READY: case START_STOP: #if 0 case VERIFY: #endif GDT_DPRINTF(GDT_D_CMD, ("opc %d tgt %d ", xs->cmd->opcode, target)); break; case REQUEST_SENSE: GDT_DPRINTF(GDT_D_CMD, ("REQUEST SENSE tgt %d ", target)); bzero(&sd, sizeof sd); sd.error_code = 0x70; sd.segment = 0; sd.flags = SKEY_NO_SENSE; gdt_enc32(sd.info, 0); sd.extra_len = 0; gdt_copy_internal_data(xs, (u_int8_t *)&sd, sizeof sd); break; case INQUIRY: GDT_DPRINTF(GDT_D_CMD, ("INQUIRY tgt %d devtype %x ", target, gdt->sc_hdr[target].hd_devtype)); bzero(&inq, sizeof inq); inq.device = (gdt->sc_hdr[target].hd_devtype & 4) ? T_CDROM : T_DIRECT; inq.dev_qual2 = (gdt->sc_hdr[target].hd_devtype & 1) ? SID_REMOVABLE : 0; inq.version = 2; inq.response_format = 2; inq.additional_length = 32; strlcpy(inq.vendor, "ICP ", sizeof inq.vendor); snprintf(inq.product, sizeof inq.product, "Host drive #%02d", target); strlcpy(inq.revision, " ", sizeof inq.revision); gdt_copy_internal_data(xs, (u_int8_t *)&inq, sizeof inq); break; case MODE_SENSE: GDT_DPRINTF(GDT_D_CMD, ("MODE SENSE tgt %d ", target)); bzero(&mpd, sizeof mpd); switch (((struct scsi_mode_sense *)xs->cmd)->page) { case 4: /* scsi_disk.h says this should be 0x16 */ mpd.dp.rigid_geometry.pg_length = 0x16; mpd.hd.data_length = sizeof mpd.hd - sizeof mpd.hd.data_length + sizeof mpd.bd + sizeof mpd.dp.rigid_geometry; mpd.hd.blk_desc_len = sizeof mpd.bd; /* XXX */ mpd.hd.dev_spec = (gdt->sc_hdr[target].hd_devtype & 2) ? 0x80 : 0; _lto3b(GDT_SECTOR_SIZE, mpd.bd.blklen); mpd.dp.rigid_geometry.pg_code = 4; _lto3b(gdt->sc_hdr[target].hd_size / gdt->sc_hdr[target].hd_heads / gdt->sc_hdr[target].hd_secs, mpd.dp.rigid_geometry.ncyl); mpd.dp.rigid_geometry.nheads = gdt->sc_hdr[target].hd_heads; gdt_copy_internal_data(xs, (u_int8_t *)&mpd, sizeof mpd); break; default: printf("%s: mode sense page %d not simulated\n", gdt->sc_dev.dv_xname, ((struct scsi_mode_sense *)xs->cmd)->page); xs->error = XS_DRIVER_STUFFUP; return (0); } break; case READ_CAPACITY: GDT_DPRINTF(GDT_D_CMD, ("READ CAPACITY tgt %d ", target)); bzero(&rcd, sizeof rcd); _lto4b(gdt->sc_hdr[target].hd_size - 1, rcd.addr); _lto4b(GDT_SECTOR_SIZE, rcd.length); gdt_copy_internal_data(xs, (u_int8_t *)&rcd, sizeof rcd); break; default: printf("gdt_internal_cache_cmd got bad opcode: %d\n", xs->cmd->opcode); xs->error = XS_DRIVER_STUFFUP; return (0); } xs->error = XS_NOERROR; return (1); } /* Start a raw SCSI operation */ int gdt_raw_scsi_cmd(xs) struct scsi_xfer *xs; { GDT_DPRINTF(GDT_D_CMD, ("gdt_raw_scsi_cmd ")); /* XXX Not yet implemented */ xs->error = XS_DRIVER_STUFFUP; return (COMPLETE); } void gdt_clear_events(gdt) struct gdt_softc *gdt; { GDT_DPRINTF(GDT_D_MISC, ("gdt_clear_events(%p) ", gdt)); /* XXX To be implemented */ } int gdt_async_event(gdt, service) struct gdt_softc *gdt; int service; { GDT_DPRINTF(GDT_D_INTR, ("gdt_async_event(%p, %d) ", gdt, service)); if (service == GDT_SCREENSERVICE) { /* XXX To be implemented */ } else { /* XXX To be implemented */ } return (0); } int gdt_sync_event(gdt, service, index, xs) struct gdt_softc *gdt; int service; u_int8_t index; struct scsi_xfer *xs; { GDT_DPRINTF(GDT_D_INTR, ("gdt_sync_event(%p, %d, %d, %p) ", gdt, service, index, xs)); if (service == GDT_SCREENSERVICE) { GDT_DPRINTF(GDT_D_INTR, ("service == GDT_SCREENSERVICE ")); /* XXX To be implemented */ return (0); } else { switch (gdt->sc_status) { case GDT_S_OK: GDT_DPRINTF(GDT_D_INTR, ("sc_status == GDT_S_OK ")); /* XXX To be implemented */ break; case GDT_S_BSY: GDT_DPRINTF(GDT_D_INTR, ("sc_status == GDT_S_BSY ")); /* XXX To be implemented */ return (2); default: GDT_DPRINTF(GDT_D_INTR, ("sc_status is %d ", gdt->sc_status)); /* XXX To be implemented */ return (0); } } return (1); } int gdt_intr(arg) void *arg; { struct gdt_softc *gdt = arg; struct gdt_intr_ctx ctx; int chain = 1; int sync_val = 0; struct scsi_xfer *xs; int prev_cmd; struct gdt_ccb *ccb; gdt_lock_t lock; GDT_DPRINTF(GDT_D_INTR, ("gdt_intr(%p) ", gdt)); /* If polling and we were not called from gdt_wait, just return */ if (gdt_polling && !gdt_from_wait) return (0); if (!gdt_polling) lock = GDT_LOCK_GDT(gdt); ctx.istatus = gdt->sc_get_status(gdt); if (!ctx.istatus) { if (!gdt_polling) GDT_UNLOCK_GDT(gdt, lock); gdt->sc_status = GDT_S_NO_STATUS; return (0); } gdt_wait_index = 0; ctx.service = ctx.info2 = 0; gdt->sc_intr(gdt, &ctx); gdt->sc_status = ctx.cmd_status; gdt->sc_info = ctx.info; gdt->sc_info2 = ctx.info2; if (gdt_from_wait) { gdt_wait_gdt = gdt; gdt_wait_index = ctx.istatus; } switch (ctx.istatus) { case GDT_ASYNCINDEX: gdt_async_event(gdt, ctx.service); goto finish; case GDT_SPEZINDEX: printf("%s: uninitialized or unknown service (%d %d)\n", gdt->sc_dev.dv_xname, ctx.info, ctx.info2); chain = 0; goto finish; } ccb = &gdt->sc_ccbs[ctx.istatus - 2]; xs = ccb->gc_xs; if (!gdt_polling) timeout_del(&xs->stimeout); ctx.service = ccb->gc_service; prev_cmd = ccb->gc_flags & GDT_GCF_CMD_MASK; if (xs && xs->cmd->opcode != PREVENT_ALLOW && xs->cmd->opcode != SYNCHRONIZE_CACHE) { bus_dmamap_sync(gdt->sc_dmat, ccb->gc_dmamap_xfer, 0, ccb->gc_dmamap_xfer->dm_mapsize, (xs->flags & SCSI_DATA_IN) ? BUS_DMASYNC_POSTREAD : BUS_DMASYNC_POSTWRITE); bus_dmamap_unload(gdt->sc_dmat, ccb->gc_dmamap_xfer); } gdt_free_ccb(gdt, ccb); switch (prev_cmd) { case GDT_GCF_UNUSED: /* XXX Not yet implemented */ chain = 0; goto finish; case GDT_GCF_INTERNAL: chain = 0; goto finish; } sync_val = gdt_sync_event(gdt, ctx.service, ctx.istatus, xs); finish: if (!gdt_polling) GDT_UNLOCK_GDT(gdt, lock); switch (sync_val) { case 1: xs->flags |= ITSDONE; scsi_done(xs); break; case 2: gdt_enqueue(gdt, xs, 0); } if (chain) gdt_chain(gdt); return (1); } void gdtminphys(bp) struct buf *bp; { GDT_DPRINTF(GDT_D_MISC, ("gdtminphys(0x%x) ", bp)); /* As this is way more than MAXPHYS it's really not necessary. */ if ((GDT_MAXOFFSETS - 1) * PAGE_SIZE < MAXPHYS && bp->b_bcount > ((GDT_MAXOFFSETS - 1) * PAGE_SIZE)) bp->b_bcount = ((GDT_MAXOFFSETS - 1) * PAGE_SIZE); minphys(bp); } int gdt_wait(gdt, ccb, timeout) struct gdt_softc *gdt; struct gdt_ccb *ccb; int timeout; { int rv = 0; GDT_DPRINTF(GDT_D_MISC, ("gdt_wait(%p, %p, %d) ", gdt, ccb, timeout)); gdt_from_wait = 1; do { if (gdt_intr(gdt) && gdt == gdt_wait_gdt && ccb->gc_cmd_index == gdt_wait_index) { rv = 1; break; } DELAY(1); } while (--timeout); gdt_from_wait = 0; while (gdt->sc_test_busy(gdt)) DELAY(0); /* XXX correct? */ return (rv); } int gdt_internal_cmd(gdt, service, opcode, arg1, arg2, arg3) struct gdt_softc *gdt; u_int8_t service; u_int16_t opcode; u_int32_t arg1, arg2, arg3; { int retries; struct gdt_ccb *ccb; GDT_DPRINTF(GDT_D_CMD, ("gdt_internal_cmd(%p, %d, %d, %d, %d, %d) ", gdt, service, opcode, arg1, arg2, arg3)); bzero(gdt->sc_cmd, GDT_CMD_SZ); for (retries = GDT_RETRIES; ; ) { ccb = gdt_get_ccb(gdt, SCSI_NOSLEEP); if (ccb == NULL) { printf("%s: no free command index found\n", gdt->sc_dev.dv_xname); return (0); } ccb->gc_service = service; gdt_ccb_set_cmd(ccb, GDT_GCF_INTERNAL); gdt->sc_set_sema0(gdt); gdt_enc32(gdt->sc_cmd + GDT_CMD_COMMANDINDEX, ccb->gc_cmd_index); gdt_enc16(gdt->sc_cmd + GDT_CMD_OPCODE, opcode); gdt_enc32(gdt->sc_cmd + GDT_CMD_BOARDNODE, GDT_LOCALBOARD); switch (service) { case GDT_CACHESERVICE: if (opcode == GDT_IOCTL) { gdt_enc32(gdt->sc_cmd + GDT_CMD_UNION + GDT_IOCTL_SUBFUNC, arg1); gdt_enc32(gdt->sc_cmd + GDT_CMD_UNION + GDT_IOCTL_CHANNEL, arg2); gdt_enc16(gdt->sc_cmd + GDT_CMD_UNION + GDT_IOCTL_PARAM_SIZE, (u_int16_t)arg3); gdt_enc32(gdt->sc_cmd + GDT_CMD_UNION + GDT_IOCTL_P_PARAM, gdt->sc_scratch_seg.ds_addr); } else { gdt_enc16(gdt->sc_cmd + GDT_CMD_UNION + GDT_CACHE_DEVICENO, (u_int16_t)arg1); gdt_enc32(gdt->sc_cmd + GDT_CMD_UNION + GDT_CACHE_BLOCKNO, arg2); } break; case GDT_SCSIRAWSERVICE: gdt_enc32(gdt->sc_cmd + GDT_CMD_UNION + GDT_RAW_DIRECTION, arg1); gdt->sc_cmd[GDT_CMD_UNION + GDT_RAW_BUS] = (u_int8_t)arg2; gdt->sc_cmd[GDT_CMD_UNION + GDT_RAW_TARGET] = (u_int8_t)arg3; gdt->sc_cmd[GDT_CMD_UNION + GDT_RAW_LUN] = (u_int8_t)(arg3 >> 8); } gdt->sc_cmd_len = GDT_CMD_SZ; gdt->sc_cmd_off = 0; gdt->sc_cmd_cnt = 0; gdt->sc_copy_cmd(gdt, ccb); gdt->sc_release_event(gdt, ccb); DELAY(20); if (!gdt_wait(gdt, ccb, GDT_POLL_TIMEOUT)) return (0); if (gdt->sc_status != GDT_S_BSY || --retries == 0) break; DELAY(1); } return (gdt->sc_status == GDT_S_OK); } struct gdt_ccb * gdt_get_ccb(gdt, flags) struct gdt_softc *gdt; int flags; { struct gdt_ccb *ccb; gdt_lock_t lock; GDT_DPRINTF(GDT_D_QUEUE, ("gdt_get_ccb(%p, 0x%x) ", gdt, flags)); lock = GDT_LOCK_GDT(gdt); for (;;) { ccb = TAILQ_FIRST(&gdt->sc_free_ccb); if (ccb != NULL) break; if (flags & SCSI_NOSLEEP) goto bail_out; tsleep(&gdt->sc_free_ccb, PRIBIO, "gdt_ccb", 0); } TAILQ_REMOVE(&gdt->sc_free_ccb, ccb, gc_chain); bail_out: GDT_UNLOCK_GDT(gdt, lock); return (ccb); } void gdt_free_ccb(gdt, ccb) struct gdt_softc *gdt; struct gdt_ccb *ccb; { gdt_lock_t lock; GDT_DPRINTF(GDT_D_QUEUE, ("gdt_free_ccb(%p, %p) ", gdt, ccb)); lock = GDT_LOCK_GDT(gdt); TAILQ_INSERT_HEAD(&gdt->sc_free_ccb, ccb, gc_chain); /* If the free list was empty, wake up potential waiters. */ if (TAILQ_NEXT(ccb, gc_chain) == NULL) wakeup(&gdt->sc_free_ccb); GDT_UNLOCK_GDT(gdt, lock); } void gdt_enqueue_ccb(gdt, ccb) struct gdt_softc *gdt; struct gdt_ccb *ccb; { GDT_DPRINTF(GDT_D_QUEUE, ("gdt_enqueue_ccb(%p, %p) ", gdt, ccb)); timeout_set(&ccb->gc_xs->stimeout, gdt_timeout, ccb); TAILQ_INSERT_TAIL(&gdt->sc_ccbq, ccb, gc_chain); gdt_start_ccbs(gdt); } void gdt_start_ccbs(gdt) struct gdt_softc *gdt; { struct gdt_ccb *ccb; struct scsi_xfer *xs; GDT_DPRINTF(GDT_D_QUEUE, ("gdt_start_ccbs(%p) ", gdt)); while ((ccb = TAILQ_FIRST(&gdt->sc_ccbq)) != NULL) { xs = ccb->gc_xs; if (ccb->gc_flags & GDT_GCF_WATCHDOG) timeout_del(&xs->stimeout); if (gdt_exec_ccb(ccb) == 0) { ccb->gc_flags |= GDT_GCF_WATCHDOG; timeout_set(&ccb->gc_xs->stimeout, gdt_watchdog, ccb); timeout_add(&xs->stimeout, (GDT_WATCH_TIMEOUT * hz) / 1000); break; } TAILQ_REMOVE(&gdt->sc_ccbq, ccb, gc_chain); if ((xs->flags & SCSI_POLL) == 0) { timeout_set(&ccb->gc_xs->stimeout, gdt_timeout, ccb); timeout_add(&xs->stimeout, (ccb->gc_timeout * hz) / 1000); } } } void gdt_chain(gdt) struct gdt_softc *gdt; { GDT_DPRINTF(GDT_D_INTR, ("gdt_chain(%p) ", gdt)); if (LIST_FIRST(&gdt->sc_queue)) gdt_scsi_cmd(LIST_FIRST(&gdt->sc_queue)); } void gdt_timeout(arg) void *arg; { struct gdt_ccb *ccb = arg; struct scsi_link *link = ccb->gc_xs->sc_link; struct gdt_softc *gdt = link->adapter_softc; gdt_lock_t lock; sc_print_addr(link); printf("timed out\n"); /* XXX Test for multiple timeouts */ ccb->gc_xs->error = XS_TIMEOUT; lock = GDT_LOCK_GDT(gdt); gdt_enqueue_ccb(gdt, ccb); GDT_UNLOCK_GDT(gdt, lock); } void gdt_watchdog(arg) void *arg; { struct gdt_ccb *ccb = arg; struct scsi_link *link = ccb->gc_xs->sc_link; struct gdt_softc *gdt = link->adapter_softc; gdt_lock_t lock; lock = GDT_LOCK_GDT(gdt); ccb->gc_flags &= ~GDT_GCF_WATCHDOG; gdt_start_ccbs(gdt); GDT_UNLOCK_GDT(gdt, lock); } #if NBIO > 0 int gdt_ioctl(dev, cmd, addr) struct device *dev; u_long cmd; caddr_t addr; { int error = 0; struct gdt_dummy *dummy; switch (cmd) { case GDT_IOCTL_DUMMY: dummy = (struct gdt_dummy *)addr; printf("%s: GDT_IOCTL_DUMMY %d\n", dev->dv_xname, dummy->x++); break; case GDT_IOCTL_GENERAL: { gdt_ucmd_t *ucmd; struct gdt_softc *gdt = (struct gdt_softc *)dev; gdt_lock_t lock; ucmd = (gdt_ucmd_t *)addr; lock = GDT_LOCK_GDT(gdt); TAILQ_INSERT_TAIL(&gdt->sc_ucmdq, ucmd, links); ucmd->complete_flag = FALSE; GDT_UNLOCK_GDT(gdt, lock); gdt_chain(gdt); if (!ucmd->complete_flag) (void)tsleep((void *)ucmd, PCATCH | PRIBIO, "gdtucw", 0); break; } case GDT_IOCTL_DRVERS: ((gdt_drvers_t *)addr)->vers = (GDT_DRIVER_VERSION << 8) | GDT_DRIVER_SUBVERSION; break; case GDT_IOCTL_CTRCNT: ((gdt_ctrcnt_t *)addr)->cnt = gdt_cnt; break; #ifdef notyet case GDT_IOCTL_CTRTYPE: { gdt_ctrt_t *p; struct gdt_softc *gdt = (struct gdt_softc *)dev; p = (gdt_ctrt_t *)addr; p->oem_id = 0x8000; p->type = 0xfd; p->info = (gdt->sc_bus << 8) | (gdt->sc_slot << 3); p->ext_type = 0x6000 | gdt->sc_subdevice; p->device_id = gdt->sc_device; p->sub_device_id = gdt->sc_subdevice; break; } #endif case GDT_IOCTL_OSVERS: { gdt_osv_t *p; p = (gdt_osv_t *)addr; p->oscode = 10; p->version = osrelease[0] - '0'; if (osrelease[1] == '.') p->subversion = osrelease[2] - '0'; else p->subversion = 0; if (osrelease[3] == '.') p->revision = osrelease[4] - '0'; else p->revision = 0; strlcpy(p->name, ostype, sizeof p->name); break; } #ifdef notyet case GDT_IOCTL_EVENT: { gdt_event_t *p; gdt_lock_t lock; p = (gdt_event_t *)addr; if (p->erase == 0xff) { if (p->dvr.event_source == GDT_ES_TEST) p->dvr.event_data.size = sizeof(p->dvr.event_data.eu.test); else if (p->dvr.event_source == GDT_ES_DRIVER) p->dvr.event_data.size = sizeof(p->dvr.event_data.eu.driver); else if (p->dvr.event_source == GDT_ES_SYNC) p->dvr.event_data.size = sizeof(p->dvr.event_data.eu.sync); else p->dvr.event_data.size = sizeof(p->dvr.event_data.eu.async); lock = GDT_LOCK_GDT(gdt); gdt_store_event(p->dvr.event_source, p->dvr.event_idx, &p->dvr.event_data); GDT_UNLOCK_GDT(gdt, lock); } else if (p->erase == 0xfe) { lock = GDT_LOCK_GDT(gdt); gdt_clear_events(); GDT_UNLOCK_GDT(gdt, lock); } else if (p->erase == 0) { p->handle = gdt_read_event(p->handle, &p->dvr); } else { gdt_readapp_event((u_int8_t)p->erase, &p->dvr); } break; } #endif case GDT_IOCTL_STATIST: #if 0 bcopy(&gdt_stat, (gdt_statist_t *)addr, sizeof gdt_stat); #else error = EOPNOTSUPP; #endif break; default: error = EINVAL; } return (error); } #endif