/*- * Copyright (c) 1998,1999 Søren Schmidt * 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, * without modification, immediately at the beginning of the file. * 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 name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission. * * 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. * * $Id: atapi-cd.c,v 1.5 1999/04/10 18:53:35 sos Exp $ */ #include "ata.h" #include "atapicd.h" #include "opt_devfs.h" #if NATA > 0 && NATAPICD > 0 #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef DEVFS #include #endif #include #include #include #include static d_open_t acdopen; static d_close_t acdclose; static d_read_t acdread; static d_write_t acdwrite; static d_ioctl_t acdioctl; static d_strategy_t acdstrategy; #define BDEV_MAJOR 31 #define CDEV_MAJOR 117 static struct cdevsw acd_cdevsw = { acdopen, acdclose, acdread, acdwrite, acdioctl, nostop, nullreset, nodevtotty, seltrue, nommap, acdstrategy, "acd", NULL, -1, nodump, nopsize, D_DISK, 0, -1 }; #define NUNIT 16 /* Max # of devices */ #define F_BOPEN 0x0001 /* The block device is opened */ #define F_MEDIA_CHANGED 0x0002 /* The media have changed since open */ #define F_LOCKED 0x0004 /* This unit is locked (or should be) */ #define F_TRACK_PREP 0x0008 /* Track should be prep'ed */ #define F_TRACK_PREPED 0x0010 /* Track has been prep'ed */ #define F_DISK_PREPED 0x0020 /* Disk has been prep'ed */ #define F_WRITTEN 0x0040 /* The medium has been written to */ static struct acd_softc *acdtab[NUNIT]; static int32_t acdnlun = 0; /* Number of configured drives */ int32_t acdattach(struct atapi_softc *); static struct acd_softc *acd_init_lun(struct atapi_softc *, int, struct devstat *); static void acd_start(struct acd_softc *); static void acd_done(struct atapi_request *); static int32_t acd_test_unit_ready (struct acd_softc *); static int32_t acd_lock_device (struct acd_softc *, int32_t); static int32_t acd_start_device (struct acd_softc *, int32_t); static int32_t acd_pause_device (struct acd_softc *, int32_t); static int32_t acd_mode_sense (struct acd_softc *, u_int8_t, void *, int32_t); static int32_t acd_mode_select (struct acd_softc *, void *, int32_t); static int32_t acd_read_toc(struct acd_softc *); static void acd_describe(struct acd_softc *); static int32_t acd_setchan(struct acd_softc *, u_int8_t, u_int8_t, u_int8_t, u_int8_t); static int32_t acd_eject(struct acd_softc *, int); static void acd_select_slot(struct acd_softc *); static int32_t acd_open_disk(struct acd_softc *, int); static int32_t acd_open_track(struct acd_softc *, struct wormio_prepare_track *); static int32_t acd_close_track(struct acd_softc *); static int32_t acd_close_disk(struct acd_softc *); static int32_t acd_read_track_info(struct acd_softc *, int, struct acd_track_info*); static int32_t acd_blank_disk(struct acd_softc *); static void lba2msf(int32_t, u_int8_t *, u_int8_t *, u_int8_t *); static int32_t msf2lba(u_int8_t, u_int8_t, u_int8_t); static void acd_drvinit(void *); int acdattach(struct atapi_softc *atp) { struct acd_softc *cdp; struct changer *chp; int32_t error, count; if (acdnlun >= NUNIT) { printf("acd: too many units\n"); return -1; } if ((cdp = acd_init_lun(atp, acdnlun, NULL)) == NULL) { printf("acd: out of memory\n"); return -1; } /* Get drive capabilities, some drives needs this repeated */ for (count = 0 ; count < 5 ; count++) { if (!(error = acd_mode_sense(cdp, ATAPI_CDROM_CAP_PAGE, &cdp->cap, sizeof(cdp->cap)))) break; } if (error) { free(cdp, M_TEMP); return -1; } cdp->cap.max_speed = ntohs(cdp->cap.max_speed); cdp->cap.max_vol_levels = ntohs(cdp->cap.max_vol_levels); cdp->cap.buf_size = ntohs(cdp->cap.buf_size); cdp->cap.cur_speed = ntohs(cdp->cap.cur_speed); acd_describe(cdp); /* If this is a changer device, allocate the neeeded lun's */ if (cdp->cap.mech == MST_MECH_CHANGER) { int8_t ccb[16] = { ATAPI_MECH_STATUS, 0, 0, 0, 0, 0, 0, 0, sizeof(struct changer)>>8, sizeof(struct changer), 0, 0, 0, 0, 0, 0 }; chp = malloc(sizeof(struct changer), M_TEMP, M_NOWAIT); if (chp == NULL) { printf("acd: out of memory\n"); return 0; } bzero(chp, sizeof(struct changer)); error = atapi_queue_cmd(cdp->atp, ccb, chp, sizeof(struct changer), A_READ, NULL, NULL, NULL); #ifdef ACD_DEBUG printf("error=%02x curr=%02x slots=%d len=%d\n", error, chp->current_slot, chp->slots, htons(chp->table_length)); #endif if (!error) { struct acd_softc *tmpcdp = cdp; int32_t count; int8_t string[16]; chp->table_length = htons(chp->table_length); for (count = 0; count < chp->slots && acdnlun < NUNIT; count++) { if (count > 0) { tmpcdp = acd_init_lun(atp, acdnlun, cdp->stats); if (!tmpcdp) { printf("acd: out of memory\n"); return -1; } } tmpcdp->slot = count; tmpcdp->changer_info = chp; printf("acd%d: changer slot %d %s\n", acdnlun, count, (chp->slot[count].present ? "CD present" : "empty")); acdtab[acdnlun++] = tmpcdp; } if (acdnlun >= NUNIT) { printf("acd: too many units\n"); return 0; } sprintf(string, "acd%d-", cdp->lun); devstat_add_entry(cdp->stats, string, tmpcdp->lun, DEV_BSIZE, DEVSTAT_NO_ORDERED_TAGS, DEVSTAT_TYPE_CDROM | DEVSTAT_TYPE_IF_IDE, 0x178); } } else { acdtab[acdnlun++] = cdp; devstat_add_entry(cdp->stats, "acd", cdp->lun, DEV_BSIZE, DEVSTAT_NO_ORDERED_TAGS, DEVSTAT_TYPE_CDROM | DEVSTAT_TYPE_IF_IDE, 0x178); } return 0; } static struct acd_softc * acd_init_lun(struct atapi_softc *atp, int32_t lun, struct devstat *stats) { struct acd_softc *acd; if (!(acd = malloc(sizeof(struct acd_softc), M_TEMP, M_NOWAIT))) return NULL; bzero(acd, sizeof(struct acd_softc)); bufq_init(&acd->buf_queue); acd->atp = atp; acd->lun = lun; acd->flags = F_MEDIA_CHANGED; acd->flags &= ~(F_WRITTEN|F_TRACK_PREP|F_TRACK_PREPED); acd->block_size = 2048; acd->refcnt = 0; acd->slot = -1; acd->changer_info = NULL; if (stats == NULL) { if (!(acd->stats = malloc(sizeof(struct devstat), M_TEMP, M_NOWAIT))) return NULL; bzero(acd->stats, sizeof(struct devstat)); } else acd->stats = stats; #ifdef DEVFS acd->a_cdevfs_token = devfs_add_devswf(&acd_cdevsw, dkmakeminor(lun, 0, 0), DV_CHR, UID_ROOT, GID_OPERATOR, 0644, "racd%da", lun); acd->c_cdevfs_token = devfs_add_devswf(&acd_cdevsw, dkmakeminor(lun, 0, RAW_PART), DV_CHR, UID_ROOT, GID_OPERATOR, 0644, "racd%dc", lun); acd->a_bdevfs_token = devfs_add_devswf(&acd_cdevsw, dkmakeminor(lun, 0, 0), DV_BLK, UID_ROOT, GID_OPERATOR, 0644, "acd%da", lun); acd->c_bdevfs_token = devfs_add_devswf(&acd_cdevsw, dkmakeminor(lun, 0, RAW_PART), DV_BLK, UID_ROOT, GID_OPERATOR, 0644, "acd%dc", lun); #endif return acd; } static void acd_describe(struct acd_softc *cdp) { int32_t comma; int8_t *mechanism; int8_t model_buf[40+1]; int8_t revision_buf[8+1]; bpack(cdp->atp->atapi_parm->model, model_buf, sizeof(model_buf)); bpack(cdp->atp->atapi_parm->revision, revision_buf, sizeof(revision_buf)); printf("acd%d: <%s/%s> CDROM drive at ata%d as %s\n", cdp->lun, model_buf, revision_buf, cdp->atp->controller->lun, (cdp->atp->unit == ATA_MASTER) ? "master" : "slave "); printf("acd%d: drive speed ", cdp->lun); if (cdp->cap.cur_speed != cdp->cap.max_speed) printf("%d - ", cdp->cap.cur_speed * 1000 / 1024); printf("%dKB/sec", cdp->cap.max_speed * 1000 / 1024); if (cdp->cap.buf_size) printf(", %dKB cache", cdp->cap.buf_size); if (cdp->atp->flags & ATAPI_F_DMA_ENABLED) printf(", DMA"); printf("\n"); printf("acd%d: supported read types:", cdp->lun); comma = 0; if (cdp->cap.read_cdr) { printf(" CD-R"); comma = 1; } if (cdp->cap.read_cdrw) { printf("%s CD-RW", comma ? "," : ""); comma = 1; } if (cdp->cap.cd_da) { printf("%s CD-DA", comma ? "," : ""); comma = 1; } if (cdp->cap.method2) printf("%s packet track", comma ? "," : ""); if (cdp->cap.write_cdr || cdp->cap.write_cdrw) { printf("\nacd%d: supported write types:", cdp->lun); comma = 0; if (cdp->cap.write_cdr) { printf(" CD-R" ); comma = 1; } if (cdp->cap.write_cdrw) { printf("%s CD-RW", comma ? "," : ""); comma = 1; } if (cdp->cap.test_write) { printf("%s test write", comma ? "," : ""); comma = 1; } } if (cdp->cap.audio_play) { printf("\nacd%d: Audio: ", cdp->lun); if (cdp->cap.audio_play) printf("play"); if (cdp->cap.max_vol_levels) printf(", %d volume levels", cdp->cap.max_vol_levels); } printf("\nacd%d: Mechanism: ", cdp->lun); switch (cdp->cap.mech) { case MST_MECH_CADDY: mechanism = "caddy"; break; case MST_MECH_TRAY: mechanism = "tray"; break; case MST_MECH_POPUP: mechanism = "popup"; break; case MST_MECH_CHANGER: mechanism = "changer"; break; case MST_MECH_CARTRIDGE: mechanism = "cartridge"; break; default: mechanism = 0; break; } if (mechanism) printf("%s%s", cdp->cap.eject ? "ejectable " : "", mechanism); else if (cdp->cap.eject) printf("ejectable"); if (cdp->cap.mech != MST_MECH_CHANGER) { printf("\nacd%d: Medium: ", cdp->lun); switch (cdp->cap.medium_type & MST_TYPE_MASK_HIGH) { case MST_CDROM: printf("CD-ROM "); break; case MST_CDR: printf("CD-R "); break; case MST_CDRW: printf("CD-RW "); break; case MST_DOOR_OPEN: printf("door open"); break; case MST_NO_DISC: printf("no/blank disc inside"); break; case MST_FMT_ERROR: printf("medium format error"); break; } if ((cdp->cap.medium_type & MST_TYPE_MASK_HIGH) < MST_TYPE_MASK_HIGH) { switch (cdp->cap.medium_type & MST_TYPE_MASK_LOW) { case MST_DATA_120: printf("120mm data disc loaded"); break; case MST_AUDIO_120: printf("120mm audio disc loaded"); break; case MST_COMB_120: printf("120mm data/audio disc loaded"); break; case MST_PHOTO_120: printf("120mm photo disc loaded"); break; case MST_DATA_80: printf("80mm data disc loaded"); break; case MST_AUDIO_80: printf("80mm audio disc loaded"); break; case MST_COMB_80: printf("80mm data/audio disc loaded"); break; case MST_PHOTO_80: printf("80mm photo disc loaded"); break; case MST_FMT_NONE: switch (cdp->cap.medium_type & MST_TYPE_MASK_HIGH) { case MST_CDROM: printf("unknown medium"); break; case MST_CDR: case MST_CDRW: printf("blank medium"); break; } break; default: printf("unknown type=0x%x", cdp->cap.medium_type); break; } } } if (cdp->cap.lock) printf(cdp->cap.locked ? ", locked" : ", unlocked"); if (cdp->cap.prevent) printf(", lock protected"); printf("\n"); } static __inline void lba2msf(int32_t lba, u_int8_t *m, u_int8_t *s, u_int8_t *f) { lba += 150; lba &= 0xffffff; *m = lba / (60 * 75); lba %= (60 * 75); *s = lba / 75; *f = lba % 75; } static __inline int32_t msf2lba(u_int8_t m, u_int8_t s, u_int8_t f) { return (m * 60 + s) * 75 + f - 150; } static int acdopen(dev_t dev, int32_t flags, int32_t fmt, struct proc *p) { int32_t lun = dkunit(dev); struct acd_softc *cdp; if (lun >= acdnlun || !(cdp = acdtab[lun])) return ENXIO; if (!(cdp->flags & F_BOPEN) && !cdp->refcnt) { acd_lock_device(cdp, 1); /* Prevent user eject */ cdp->flags |= F_LOCKED; } if (fmt == S_IFBLK) cdp->flags |= F_BOPEN; else cdp->refcnt++; if (!(flags & O_NONBLOCK)) { if (acd_read_toc(cdp)) { if (!(flags & FWRITE)) { printf("acd%d: read_toc failed\n", lun); return EIO; } } } return 0; } static int acdclose(dev_t dev, int32_t flags, int32_t fmt, struct proc *p) { int32_t lun = dkunit(dev); struct acd_softc *cdp; if (lun >= acdnlun || !(cdp = acdtab[lun])) return ENXIO; if (fmt == S_IFBLK) cdp->flags &= ~F_BOPEN; else cdp->refcnt--; /* Are we the last open ?? */ if (!(cdp->flags & F_BOPEN) && !cdp->refcnt) { /* Yup, do we need to close any written tracks */ if ((flags & FWRITE) != 0) { if ((cdp->flags & F_TRACK_PREPED) != 0) { acd_close_track(cdp); cdp->flags &= ~(F_TRACK_PREPED | F_TRACK_PREP); } } acd_lock_device(cdp, 0); /* Allow the user eject */ } cdp->flags &= ~F_LOCKED; return 0; } static int acdread(dev_t dev, struct uio *uio, int32_t ioflag) { return physio(acdstrategy, NULL, dev, 1, minphys, uio); } static int acdwrite(dev_t dev, struct uio *uio, int32_t ioflag) { return physio(acdstrategy, NULL, dev, 0, minphys, uio); } static int acdioctl(dev_t dev, u_long cmd, caddr_t addr, int32_t flag, struct proc *p) { int32_t lun = dkunit(dev); struct acd_softc *cdp = acdtab[lun]; int32_t error = 0; if (cdp->flags & F_MEDIA_CHANGED) switch (cmd) { case CDIOCRESET: break; default: acd_read_toc(cdp); acd_lock_device(cdp, 1); cdp->flags |= F_LOCKED; break; } switch (cmd) { case CDIOCRESUME: return acd_pause_device(cdp, 1); case CDIOCPAUSE: return acd_pause_device(cdp, 0); case CDIOCSTART: return acd_start_device(cdp, 1); case CDIOCSTOP: return acd_start_device(cdp, 0); case CDIOCALLOW: acd_select_slot(cdp); cdp->flags &= ~F_LOCKED; return acd_lock_device(cdp, 0); case CDIOCPREVENT: acd_select_slot(cdp); cdp->flags |= F_LOCKED; return acd_lock_device(cdp, 1); case CDIOCRESET: error = suser(p); if (error) return error; return acd_test_unit_ready(cdp); case CDIOCEJECT: if ((cdp->flags & F_BOPEN) && cdp->refcnt) return EBUSY; return acd_eject(cdp, 0); case CDIOCCLOSE: if ((cdp->flags & F_BOPEN) && cdp->refcnt) return 0; return acd_eject(cdp, 1); case CDIOREADTOCHEADER: if (!cdp->toc.hdr.ending_track) return EIO; bcopy(&cdp->toc.hdr, addr, sizeof(cdp->toc.hdr)); break; case CDIOREADTOCENTRYS: { struct ioc_read_toc_entry *te = (struct ioc_read_toc_entry *)addr; struct toc *toc = &cdp->toc; struct toc buf; u_int32_t len; u_int8_t starting_track = te->starting_track; if (!cdp->toc.hdr.ending_track) return EIO; if (te->data_len < sizeof(toc->tab[0]) || (te->data_len % sizeof(toc->tab[0])) != 0 || (te->address_format != CD_MSF_FORMAT && te->address_format != CD_LBA_FORMAT)) return EINVAL; if (!starting_track) starting_track = toc->hdr.starting_track; else if (starting_track == 170) starting_track = toc->hdr.ending_track + 1; else if (starting_track < toc->hdr.starting_track || starting_track > toc->hdr.ending_track + 1) return EINVAL; len = ((toc->hdr.ending_track + 1 - starting_track) + 1) * sizeof(toc->tab[0]); if (te->data_len < len) len = te->data_len; if (len > sizeof(toc->tab)) return EINVAL; if (te->address_format == CD_MSF_FORMAT) { struct cd_toc_entry *entry; buf = cdp->toc; toc = &buf; entry = toc->tab + (toc->hdr.ending_track + 1 - toc->hdr.starting_track) + 1; while (--entry >= toc->tab) lba2msf(ntohl(entry->addr.lba), &entry->addr.msf.minute, &entry->addr.msf.second, &entry->addr.msf.frame); } return copyout(toc->tab + starting_track - toc->hdr.starting_track, te->data, len); } case CDIOREADTOCENTRY: { struct ioc_read_toc_single_entry *te = (struct ioc_read_toc_single_entry *)addr; struct toc *toc = &cdp->toc; struct toc buf; u_int8_t track = te->track; if (!cdp->toc.hdr.ending_track) return EIO; if (te->address_format != CD_MSF_FORMAT && te->address_format != CD_LBA_FORMAT) return EINVAL; if (!track) track = toc->hdr.starting_track; else if (track == 170) track = toc->hdr.ending_track + 1; else if (track < toc->hdr.starting_track || track > toc->hdr.ending_track + 1) return EINVAL; if (te->address_format == CD_MSF_FORMAT) { struct cd_toc_entry *entry; buf = cdp->toc; toc = &buf; entry = toc->tab + (track - toc->hdr.starting_track); lba2msf(ntohl(entry->addr.lba), &entry->addr.msf.minute, &entry->addr.msf.second, &entry->addr.msf.frame); } bcopy(toc->tab + track - toc->hdr.starting_track, &te->entry, sizeof(struct cd_toc_entry)); } break; case CDIOCREADSUBCHANNEL: { struct ioc_read_subchannel *args = (struct ioc_read_subchannel *)addr; struct cd_sub_channel_info data; u_int32_t len = args->data_len; int32_t abslba, rellba; int8_t ccb[16] = { ATAPI_READ_SUBCHANNEL, 0, 0x40, 1, 0, 0, 0, sizeof(cdp->subchan)>>8, sizeof(cdp->subchan), 0, 0, 0, 0, 0, 0, 0 }; if (len > sizeof(data) || len < sizeof(struct cd_sub_channel_header)) return EINVAL; if (atapi_queue_cmd(cdp->atp, ccb, &cdp->subchan, sizeof(cdp->subchan), A_READ, NULL, NULL, NULL)) return EIO; #ifdef ACD_DEBUG atapi_dump("acd: subchan", &cdp->subchan, sizeof(cdp->subchan)); #endif abslba = cdp->subchan.abslba; rellba = cdp->subchan.rellba; if (args->address_format == CD_MSF_FORMAT) { lba2msf(ntohl(abslba), &data.what.position.absaddr.msf.minute, &data.what.position.absaddr.msf.second, &data.what.position.absaddr.msf.frame); lba2msf(ntohl(rellba), &data.what.position.reladdr.msf.minute, &data.what.position.reladdr.msf.second, &data.what.position.reladdr.msf.frame); } else { data.what.position.absaddr.lba = abslba; data.what.position.reladdr.lba = rellba; } data.header.audio_status = cdp->subchan.audio_status; data.what.position.control = cdp->subchan.control & 0xf; data.what.position.addr_type = cdp->subchan.control >> 4; data.what.position.track_number = cdp->subchan.track; data.what.position.index_number = cdp->subchan.indx; return copyout(&data, args->data, len); } case CDIOCPLAYMSF: { struct ioc_play_msf *args = (struct ioc_play_msf *)addr; int8_t ccb[16] = { ATAPI_PLAY_MSF, 0, 0, args->start_m, args->start_s, args->start_f, args->end_m, args->end_s, args->end_f, 0, 0, 0, 0, 0, 0, 0 }; return atapi_queue_cmd(cdp->atp, ccb, NULL, 0, 0, NULL, NULL, NULL); } case CDIOCPLAYBLOCKS: { struct ioc_play_blocks *args = (struct ioc_play_blocks *)addr; int8_t ccb[16] = { ATAPI_PLAY_BIG, 0, args->blk>>24, args->blk>>16, args->blk>>8, args->blk, args->len>>24, args->len>>16, args->len>>8, args->len, 0, 0, 0, 0, 0, 0 }; return atapi_queue_cmd(cdp->atp, ccb, NULL, 0, 0, NULL, NULL, NULL); } case CDIOCPLAYTRACKS: { struct ioc_play_track *args = (struct ioc_play_track *)addr; u_int32_t start, len; int32_t t1, t2; int8_t ccb[16]; if (!cdp->toc.hdr.ending_track) return EIO; if (args->end_track < cdp->toc.hdr.ending_track + 1) ++args->end_track; if (args->end_track > cdp->toc.hdr.ending_track + 1) args->end_track = cdp->toc.hdr.ending_track + 1; t1 = args->start_track - cdp->toc.hdr.starting_track; t2 = args->end_track - cdp->toc.hdr.starting_track; if (t1 < 0 || t2 < 0) return EINVAL; start = ntohl(cdp->toc.tab[t1].addr.lba); len = ntohl(cdp->toc.tab[t2].addr.lba) - start; bzero(ccb, sizeof(ccb)); ccb[0] = ATAPI_PLAY_BIG; ccb[2] = start>>24; ccb[3] = start>>16; ccb[4] = start>>8; ccb[5] = start; ccb[6] = len>>24; ccb[7] = len>>16; ccb[8] = len>>8; ccb[9] = len; return atapi_queue_cmd(cdp->atp, ccb, NULL, 0, 0, NULL, NULL, NULL); } case CDIOCREADAUDIO: { struct ioc_read_audio *args = (struct ioc_read_audio *)addr; int32_t lba, frames, error = 0; u_int8_t *buffer, *ubuf = args->buffer; int8_t ccb[16]; if (!cdp->toc.hdr.ending_track) return EIO; if ((frames = args->nframes) < 0) return EINVAL; if (args->address_format == CD_LBA_FORMAT) lba = args->address.lba; else if (args->address_format == CD_MSF_FORMAT) lba = msf2lba(args->address.msf.minute, args->address.msf.second, args->address.msf.frame); else return EINVAL; #ifndef CD_BUFFER_BLOCKS #define CD_BUFFER_BLOCKS 13 #endif if (!(buffer = malloc(CD_BUFFER_BLOCKS * 2352, M_TEMP,M_NOWAIT))) return ENOMEM; bzero(ccb, sizeof(ccb)); while (frames > 0) { int32_t size; u_int8_t blocks; blocks = (frames>CD_BUFFER_BLOCKS) ? CD_BUFFER_BLOCKS : frames; size = blocks * 2352; ccb[0] = ATAPI_READ_CD; ccb[1] = 4; ccb[2] = lba>>24; ccb[3] = lba>>16; ccb[4] = lba>>8; ccb[5] = lba; ccb[8] = blocks; ccb[9] = 0xf0; if ((error = atapi_queue_cmd(cdp->atp, ccb, buffer, size, A_READ, NULL, NULL, NULL))) break; if ((error = copyout(buffer, ubuf, size))) break; ubuf += size; frames -= blocks; lba += blocks; } free(buffer, M_TEMP); if (args->address_format == CD_LBA_FORMAT) args->address.lba = lba; else if (args->address_format == CD_MSF_FORMAT) lba2msf(lba, &args->address.msf.minute, &args->address.msf.second, &args->address.msf.frame); return error; } case CDIOCGETVOL: { struct ioc_vol *arg = (struct ioc_vol *)addr; if ((error = acd_mode_sense(cdp, ATAPI_CDROM_AUDIO_PAGE, &cdp->au, sizeof(cdp->au)))) return error; if (cdp->au.page_code != ATAPI_CDROM_AUDIO_PAGE) return EIO; arg->vol[0] = cdp->au.port[0].volume; arg->vol[1] = cdp->au.port[1].volume; arg->vol[2] = cdp->au.port[2].volume; arg->vol[3] = cdp->au.port[3].volume; } break; case CDIOCSETVOL: { struct ioc_vol *arg = (struct ioc_vol *)addr; if ((error = acd_mode_sense(cdp, ATAPI_CDROM_AUDIO_PAGE, &cdp->au, sizeof(cdp->au)))) return error; if (cdp->au.page_code != ATAPI_CDROM_AUDIO_PAGE) return EIO; if ((error = acd_mode_sense(cdp, ATAPI_CDROM_AUDIO_PAGE_MASK, &cdp->aumask, sizeof(cdp->aumask)))) return error; cdp->au.data_length = 0; cdp->au.port[0].channels = CHANNEL_0; cdp->au.port[1].channels = CHANNEL_1; cdp->au.port[0].volume = arg->vol[0] & cdp->aumask.port[0].volume; cdp->au.port[1].volume = arg->vol[1] & cdp->aumask.port[1].volume; cdp->au.port[2].volume = arg->vol[2] & cdp->aumask.port[2].volume; cdp->au.port[3].volume = arg->vol[3] & cdp->aumask.port[3].volume; return acd_mode_select(cdp, &cdp->au, sizeof(cdp->au)); } case CDIOCSETPATCH: { struct ioc_patch *arg = (struct ioc_patch *)addr; return acd_setchan(cdp, arg->patch[0], arg->patch[1], arg->patch[2], arg->patch[3]); } case CDIOCSETMONO: return acd_setchan(cdp, CHANNEL_0|CHANNEL_1, CHANNEL_0|CHANNEL_1, 0, 0); case CDIOCSETSTEREO: return acd_setchan(cdp, CHANNEL_0, CHANNEL_1, 0, 0); case CDIOCSETMUTE: return acd_setchan(cdp, 0, 0, 0, 0); case CDIOCSETLEFT: return acd_setchan(cdp, CHANNEL_0, CHANNEL_0, 0, 0); case CDIOCSETRIGHT: return acd_setchan(cdp, CHANNEL_1, CHANNEL_1, 0, 0); case CDRIOCNEXTWRITEABLEADDR: { struct acd_track_info track_info; if ((error = acd_read_track_info(cdp, 0xff, &track_info))) break; if (!track_info.nwa_valid) return EINVAL; cdp->next_writeable_lba = track_info.next_writeable_addr; *(int*)addr = track_info.next_writeable_addr; } break; case WORMIOCPREPDISK: { struct wormio_prepare_disk *w = (struct wormio_prepare_disk *)addr; if (w->dummy != 0 && w->dummy != 1) error = EINVAL; else { error = acd_open_disk(cdp, w->dummy); if (error == 0) { cdp->flags |= F_DISK_PREPED; cdp->dummy = w->dummy; cdp->speed = w->speed; } } } break; case WORMIOCPREPTRACK: { struct wormio_prepare_track *w =(struct wormio_prepare_track *)addr; if (w->audio != 0 && w->audio != 1) error = EINVAL; else if (w->audio == 0 && w->preemp) error = EINVAL; else if ((cdp->flags & F_DISK_PREPED) == 0) { error = EINVAL; printf("acd%d: sequence error (PREP_TRACK)\n", cdp->lun); } else { cdp->flags |= F_TRACK_PREP; cdp->preptrack = *w; } } break; case WORMIOCFINISHTRACK: if ((cdp->flags & F_TRACK_PREPED) != 0) error = acd_close_track(cdp); cdp->flags &= ~(F_TRACK_PREPED | F_TRACK_PREP); break; case WORMIOCFIXATION: { struct wormio_fixation *w = (struct wormio_fixation *)addr; if ((cdp->flags & F_WRITTEN) == 0) error = EINVAL; else if (w->toc_type < 0 /* WORM_TOC_TYPE_AUDIO */ || w->toc_type > 4 /* WORM_TOC_TYPE_CDI */ ) error = EINVAL; else if (w->onp != 0 && w->onp != 1) error = EINVAL; else { /* no fixation needed if dummy write */ if (cdp->dummy == 0) error = acd_close_disk(cdp); cdp->flags &= ~(F_WRITTEN|F_DISK_PREPED|F_TRACK_PREP|F_TRACK_PREPED); } } break; case CDRIOCBLANK: return acd_blank_disk(cdp); default: return ENOTTY; } return error; } static void acdstrategy(struct buf *bp) { int32_t lun = dkunit(bp->b_dev); struct acd_softc *cdp = acdtab[lun]; int32_t x; #ifdef NOTYET /* allow write only on CD-R/RW media */ /* all for now SOS */ if (!(bp->b_flags & B_READ) && !(writeable_media)) { bp->b_error = EROFS; bp->b_flags |= B_ERROR; biodone(bp); return; } #endif if (bp->b_bcount == 0) { bp->b_resid = 0; biodone(bp); return; } /* check for valid blocksize SOS */ bp->b_pblkno = bp->b_blkno; bp->b_resid = bp->b_bcount; x = splbio(); bufqdisksort(&cdp->buf_queue, bp); acd_start(cdp); splx(x); } static void acd_start(struct acd_softc *cdp) { struct buf *bp = bufq_first(&cdp->buf_queue); u_int32_t lba, count; int8_t ccb[16]; if (!bp) return; bufq_remove(&cdp->buf_queue, bp); /* Should reject all queued entries if media have changed. */ if (cdp->flags & F_MEDIA_CHANGED) { bp->b_error = EIO; bp->b_flags |= B_ERROR; biodone(bp); return; } acd_select_slot(cdp); if ((bp->b_flags & B_READ) == B_WRITE) { if ((cdp->flags & F_TRACK_PREPED) == 0) { if ((cdp->flags & F_TRACK_PREP) == 0) { printf("acd%d: sequence error\n", cdp->lun); bp->b_error = EIO; bp->b_flags |= B_ERROR; biodone(bp); return; } else { if (acd_open_track(cdp, &cdp->preptrack) != 0) { biodone(bp); return; } cdp->flags |= F_TRACK_PREPED; } } } bzero(ccb, sizeof(ccb)); if (bp->b_flags & B_READ) { lba = bp->b_blkno / (cdp->block_size / DEV_BSIZE); ccb[0] = ATAPI_READ_BIG; } else { lba = cdp->next_writeable_lba + (bp->b_offset / cdp->block_size); ccb[0] = ATAPI_WRITE_BIG; } count = (bp->b_bcount + (cdp->block_size - 1)) / cdp->block_size; #ifdef ACD_DEBUG printf("acd%d: lba=%d, count=%d\n", cdp->lun, lba, count); #endif ccb[1] = 0; ccb[2] = lba>>24; ccb[3] = lba>>16; ccb[4] = lba>>8; ccb[5] = lba; ccb[7] = count>>8; ccb[8] = count; devstat_start_transaction(cdp->stats); atapi_queue_cmd(cdp->atp, ccb, bp->b_data, bp->b_bcount, (bp->b_flags&B_READ)?A_READ : 0, acd_done, cdp, (void *)bp); } static void acd_done(struct atapi_request *request) { struct buf *bp = request->bp; struct acd_softc *cdp = request->driver; devstat_end_transaction(cdp->stats, bp->b_bcount-request->bytecount, DEVSTAT_TAG_NONE, (bp->b_flags&B_READ) ? DEVSTAT_READ:DEVSTAT_WRITE); if (request->result) { atapi_error(request->device, request->result); bp->b_error = EIO; bp->b_flags |= B_ERROR; } else { bp->b_resid = request->bytecount; if ((bp->b_flags & B_READ) == B_WRITE) cdp->flags |= F_WRITTEN; } biodone(bp); acd_start(cdp); } static int32_t acd_test_unit_ready(struct acd_softc *cdp) { int8_t ccb[16] = { ATAPI_TEST_UNIT_READY, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; return atapi_queue_cmd(cdp->atp, ccb, NULL, 0, 0, NULL, NULL, NULL); } static int32_t acd_lock_device(struct acd_softc *cdp, int32_t lock) { int8_t ccb[16] = { ATAPI_PREVENT_ALLOW, 0, 0, 0, lock, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; return atapi_queue_cmd(cdp->atp, ccb, NULL, 0, 0, NULL, NULL, NULL); } static int32_t acd_start_device(struct acd_softc *cdp, int32_t start) { int8_t ccb[16] = { ATAPI_START_STOP, 0, 0, 0, start, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; return atapi_queue_cmd(cdp->atp, ccb, NULL, 0, 0, NULL, NULL, NULL); } static int32_t acd_pause_device(struct acd_softc *cdp, int32_t pause) { int8_t ccb[16] = { ATAPI_START_STOP, 0, 0, 0, 0, 0, 0, 0, pause, 0, 0, 0, 0, 0, 0, 0 }; return atapi_queue_cmd(cdp->atp, ccb, NULL, 0, 0, NULL, NULL, NULL); } static int32_t acd_mode_sense(struct acd_softc *cdp, u_int8_t page, void *pagebuf, int32_t pagesize) { int32_t error; int8_t ccb[16] = { ATAPI_MODE_SENSE, 0, page, 0, 0, 0, 0, pagesize>>8, pagesize, 0, 0, 0, 0, 0, 0, 0 }; error = atapi_queue_cmd(cdp->atp, ccb, pagebuf, pagesize, A_READ, NULL, NULL, NULL); #ifdef ACD_DEBUG atapi_dump("acd: mode sense ", pagebuf, pagesize); #endif return error; } static int32_t acd_mode_select(struct acd_softc *cdp, void *pagebuf, int32_t pagesize) { int8_t ccb[16] = { ATAPI_MODE_SELECT, 0x10, 0, 0, 0, 0, 0, pagesize>>8, pagesize, 0, 0, 0, 0, 0, 0, 0 }; #ifdef ACD_DEBUG printf("acd: modeselect pagesize=%d\n", pagesize); atapi_dump("acd: mode select ", pagebuf, pagesize); #endif return atapi_queue_cmd(cdp->atp, ccb, pagebuf, pagesize, 0, NULL, NULL, NULL); } static int32_t acd_read_toc(struct acd_softc *cdp) { int32_t error, ntracks, len; int8_t ccb[16]; bzero(&cdp->toc, sizeof(cdp->toc)); bzero(&cdp->info, sizeof(cdp->info)); bzero(ccb, sizeof(ccb)); acd_select_slot(cdp); error = acd_test_unit_ready(cdp); if ((error & ATAPI_SK_MASK) == ATAPI_SK_UNIT_ATTENTION) { cdp->flags |= F_MEDIA_CHANGED; cdp->flags &= ~(F_WRITTEN | F_TRACK_PREP | F_TRACK_PREPED); error = acd_test_unit_ready(cdp); } if (error) { atapi_error(cdp->atp, error); return EIO; } cdp->flags &= ~F_MEDIA_CHANGED; len = sizeof(struct ioc_toc_header) + sizeof(struct cd_toc_entry); ccb[0] = ATAPI_READ_TOC; ccb[7] = len>>8; ccb[8] = len; if (atapi_queue_cmd(cdp->atp, ccb, &cdp->toc, len, A_READ, NULL,NULL,NULL)){ bzero(&cdp->toc, sizeof(cdp->toc)); return 0; } ntracks = cdp->toc.hdr.ending_track - cdp->toc.hdr.starting_track + 1; if (ntracks <= 0 || ntracks > MAXTRK) { bzero(&cdp->toc, sizeof(cdp->toc)); return 0; } len = sizeof(struct ioc_toc_header) + ntracks * sizeof(struct cd_toc_entry); bzero(ccb, sizeof(ccb)); ccb[0] = ATAPI_READ_TOC; ccb[7] = len>>8; ccb[8] = len; if (atapi_queue_cmd(cdp->atp, ccb, &cdp->toc, len, A_READ, NULL,NULL,NULL)){ bzero(&cdp->toc, sizeof(cdp->toc)); return 0; } cdp->toc.hdr.len = ntohs(cdp->toc.hdr.len); bzero(ccb, sizeof(ccb)); ccb[0] = ATAPI_READ_CAPACITY; if (atapi_queue_cmd(cdp->atp, ccb, &cdp->info, sizeof(cdp->info), A_READ, NULL, NULL, NULL)) bzero(&cdp->info, sizeof(cdp->info)); cdp->toc.tab[ntracks].control = cdp->toc.tab[ntracks - 1].control; cdp->toc.tab[ntracks].addr_type = cdp->toc.tab[ntracks - 1].addr_type; cdp->toc.tab[ntracks].track = 170; cdp->toc.tab[ntracks].addr.lba = cdp->info.volsize; cdp->info.volsize = ntohl(cdp->info.volsize); cdp->info.blksize = ntohl(cdp->info.blksize); #ifdef ACD_DEBUG if (cdp->info.volsize && cdp->toc.hdr.ending_track) { printf("acd%d: ", cdp->lun); if (cdp->toc.tab[0].control & 4) printf("%dMB ", cdp->info.volsize / 512); else printf("%d:%d audio ", cdp->info.volsize / 75 / 60, cdp->info.volsize / 75 % 60); printf("(%d sectors (%d bytes)), %d tracks\n", cdp->info.volsize, cdp->info.blksize, cdp->toc.hdr.ending_track - cdp->toc.hdr.starting_track + 1); } #endif return 0; } static int32_t acd_setchan(struct acd_softc *cdp, u_int8_t c0, u_int8_t c1, u_int8_t c2, u_int8_t c3) { int32_t error; if ((error = acd_mode_sense(cdp, ATAPI_CDROM_AUDIO_PAGE, &cdp->au, sizeof(cdp->au)))) return error; if (cdp->au.page_code != ATAPI_CDROM_AUDIO_PAGE) return EIO; cdp->au.data_length = 0; cdp->au.port[0].channels = c0; cdp->au.port[1].channels = c1; cdp->au.port[2].channels = c2; cdp->au.port[3].channels = c3; return acd_mode_select(cdp, &cdp->au, sizeof(cdp->au)); } static int32_t acd_eject(struct acd_softc *cdp, int32_t close) { int32_t error; acd_select_slot(cdp); error = acd_start_device(cdp, 0); if ((error & ATAPI_SK_MASK) && ((error & ATAPI_SK_MASK) == ATAPI_SK_NOT_READY || (error & ATAPI_SK_MASK) == ATAPI_SK_UNIT_ATTENTION)) { if (!close) return 0; if ((error = acd_start_device(cdp, 3))) return error; acd_read_toc(cdp); acd_lock_device(cdp, 1); cdp->flags |= F_LOCKED; return 0; } if (error) { atapi_error(cdp->atp, error); return EIO; } if (close) return 0; tsleep((caddr_t) &lbolt, PRIBIO, "acdej1", 0); tsleep((caddr_t) &lbolt, PRIBIO, "acdej2", 0); acd_lock_device(cdp, 0); cdp->flags &= ~F_LOCKED; cdp->flags |= F_MEDIA_CHANGED; cdp->flags &= ~(F_WRITTEN|F_TRACK_PREP|F_TRACK_PREPED); return acd_start_device(cdp, 2); } static void acd_select_slot(struct acd_softc *cdp) { int8_t ccb[16]; if (cdp->slot < 0 || cdp->changer_info->current_slot == cdp->slot) return; /* Unlock (might not be needed but its cheaper than asking) */ acd_lock_device(cdp, 0); bzero(ccb, sizeof(ccb)); /* Unload the current media from player */ ccb[0] = ATAPI_LOAD_UNLOAD; ccb[4] = 2; ccb[8] = cdp->changer_info->current_slot; atapi_queue_cmd(cdp->atp, ccb, NULL, 0, 0, NULL, NULL, NULL); /* load the wanted slot */ ccb[0] = ATAPI_LOAD_UNLOAD; ccb[4] = 3; ccb[8] = cdp->slot; atapi_queue_cmd(cdp->atp, ccb, NULL, 0, 0, NULL, NULL, NULL); cdp->changer_info->current_slot = cdp->slot; /* Lock the media if needed */ if (cdp->flags & F_LOCKED) acd_lock_device(cdp, 1); } static int32_t acd_open_disk(struct acd_softc *cdp, int32_t test) { cdp->next_writeable_lba = 0; return 0; } static int32_t acd_close_disk(struct acd_softc *cdp) { int8_t ccb[16]; bzero(ccb, sizeof(ccb)); ccb[0] = ATAPI_CLOSE_TRACK; ccb[2] = 2; ccb[5] = 0; /* track to close (0 = last open) */ return atapi_queue_cmd(cdp->atp, ccb, NULL, 0, 0, NULL, NULL, NULL); } static int32_t acd_open_track(struct acd_softc *cdp, struct wormio_prepare_track *ptp) { struct write_param param; int32_t error; if ((error = acd_mode_sense(cdp, ATAPI_CDROM_WRITE_PARAMETERS_PAGE, ¶m, sizeof(param)))) return error; param.page_code = 0x05; param.page_length = 0x32; param.test_write = cdp->dummy ? 1 : 0; param.write_type = CDR_WTYPE_TRACK; switch (ptp->audio) { /* switch (data_type) { */ case 0: /* case CDR_DATA: */ cdp->block_size = 2048; param.track_mode = CDR_TMODE_DATA; param.data_block_type = CDR_DB_ROM_MODE1; param.session_format = CDR_SESS_CDROM; break; default: /* case CDR_AUDIO: */ cdp->block_size = 2352; if (ptp->preemp) param.track_mode = CDR_TMODE_AUDIO; else param.track_mode = 0; param.data_block_type = CDR_DB_RAW; param.session_format = CDR_SESS_CDROM; break; /* case CDR_MODE2: param.track_mode = CDR_TMODE_DATA; param.data_block_type = CDR_DB_ROM_MODE2; param.session_format = CDR_SESS_CDROM; break; case CDR_XA1: param.track_mode = CDR_TMODE_DATA; param.data_block_type = CDR_DB_XA_MODE1; param.session_format = CDR_SESS_CDROM_XA; break; case CDR_XA2: param.track_mode = CDR_TMODE_DATA; param.data_block_type = CDR_DB_XA_MODE2_F1; param.session_format = CDR_SESS_CDROM_XA; break; case CDR_CDI: param.track_mode = CDR_TMODE_DATA; param.data_block_type = CDR_DB_XA_MODE2_F1; param.session_format = CDR_SESS_CDI; break; } */ } param.multi_session = CDR_MSES_NONE; param.fp = 0; param.packet_size = 0; return acd_mode_select(cdp, ¶m, sizeof(param)); } static int32_t acd_close_track(struct acd_softc *cdp) { int8_t ccb[16]; bzero(ccb, sizeof(ccb)); ccb[0] = ATAPI_SYNCHRONIZE_CACHE; return atapi_queue_cmd(cdp->atp, ccb, NULL, 0, 0, NULL, NULL, NULL); } static int32_t acd_read_track_info(struct acd_softc *cdp, int32_t lba, struct acd_track_info *info) { int32_t error; int8_t ccb[16] = { ATAPI_READ_TRACK_INFO, 1, lba>>24, lba>>16, lba>>8, lba, 0, sizeof(*info)>>8, sizeof(*info), 0, 0, 0, 0, 0, 0, 0 }; if ((error = atapi_queue_cmd(cdp->atp, ccb, info, sizeof(*info), A_READ, NULL, NULL, NULL))) return error; info->track_start_addr = ntohl(info->track_start_addr); info->next_writeable_addr = ntohl(info->next_writeable_addr); info->free_blocks = ntohl(info->free_blocks); info->fixed_packet_size = ntohl(info->fixed_packet_size); info->track_length = ntohl(info->track_length); return 0; } static int32_t acd_blank_disk(struct acd_softc *cdp) { int32_t error; int8_t ccb[16]; bzero(ccb, sizeof(ccb)); ccb[0] = ATAPI_BLANK; ccb[1] = 1; error = atapi_queue_cmd(cdp->atp, ccb, NULL, 0, 0, NULL, NULL, NULL); cdp->flags |= F_MEDIA_CHANGED; cdp->flags &= ~(F_WRITTEN|F_TRACK_PREP|F_TRACK_PREPED); return error; } static void acd_drvinit(void *unused) { static int32_t acd_devsw_installed = 0; if (!acd_devsw_installed) { cdevsw_add_generic(BDEV_MAJOR, CDEV_MAJOR, &acd_cdevsw); acd_devsw_installed = 1; } } SYSINIT(acddev, SI_SUB_DRIVERS, SI_ORDER_MIDDLE, acd_drvinit, NULL) #endif /* NATA && NATAPICD */