freebsd-dev/sys/dev/aac/aac.c

3815 lines
100 KiB
C

/*-
* SPDX-License-Identifier: BSD-2-Clause-FreeBSD
*
* Copyright (c) 2000 Michael Smith
* Copyright (c) 2001 Scott Long
* Copyright (c) 2000 BSDi
* Copyright (c) 2001 Adaptec, Inc.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
/*
* Driver for the Adaptec 'FSA' family of PCI/SCSI RAID adapters.
*/
#define AAC_DRIVERNAME "aac"
#include "opt_aac.h"
/* #include <stddef.h> */
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/malloc.h>
#include <sys/kernel.h>
#include <sys/kthread.h>
#include <sys/proc.h>
#include <sys/sysctl.h>
#include <sys/sysent.h>
#include <sys/poll.h>
#include <sys/ioccom.h>
#include <sys/bus.h>
#include <sys/conf.h>
#include <sys/signalvar.h>
#include <sys/time.h>
#include <sys/eventhandler.h>
#include <sys/rman.h>
#include <machine/bus.h>
#include <machine/resource.h>
#include <dev/pci/pcireg.h>
#include <dev/pci/pcivar.h>
#include <dev/aac/aacreg.h>
#include <sys/aac_ioctl.h>
#include <dev/aac/aacvar.h>
#include <dev/aac/aac_tables.h>
static void aac_startup(void *arg);
static void aac_add_container(struct aac_softc *sc,
struct aac_mntinforesp *mir, int f);
static void aac_get_bus_info(struct aac_softc *sc);
static void aac_daemon(void *arg);
/* Command Processing */
static void aac_timeout(struct aac_softc *sc);
static void aac_complete(void *context, int pending);
static int aac_bio_command(struct aac_softc *sc, struct aac_command **cmp);
static void aac_bio_complete(struct aac_command *cm);
static int aac_wait_command(struct aac_command *cm);
static void aac_command_thread(struct aac_softc *sc);
/* Command Buffer Management */
static void aac_map_command_sg(void *arg, bus_dma_segment_t *segs,
int nseg, int error);
static void aac_map_command_helper(void *arg, bus_dma_segment_t *segs,
int nseg, int error);
static int aac_alloc_commands(struct aac_softc *sc);
static void aac_free_commands(struct aac_softc *sc);
static void aac_unmap_command(struct aac_command *cm);
/* Hardware Interface */
static int aac_alloc(struct aac_softc *sc);
static void aac_common_map(void *arg, bus_dma_segment_t *segs, int nseg,
int error);
static int aac_check_firmware(struct aac_softc *sc);
static int aac_init(struct aac_softc *sc);
static int aac_sync_command(struct aac_softc *sc, u_int32_t command,
u_int32_t arg0, u_int32_t arg1, u_int32_t arg2,
u_int32_t arg3, u_int32_t *sp);
static int aac_setup_intr(struct aac_softc *sc);
static int aac_enqueue_fib(struct aac_softc *sc, int queue,
struct aac_command *cm);
static int aac_dequeue_fib(struct aac_softc *sc, int queue,
u_int32_t *fib_size, struct aac_fib **fib_addr);
static int aac_enqueue_response(struct aac_softc *sc, int queue,
struct aac_fib *fib);
/* StrongARM interface */
static int aac_sa_get_fwstatus(struct aac_softc *sc);
static void aac_sa_qnotify(struct aac_softc *sc, int qbit);
static int aac_sa_get_istatus(struct aac_softc *sc);
static void aac_sa_clear_istatus(struct aac_softc *sc, int mask);
static void aac_sa_set_mailbox(struct aac_softc *sc, u_int32_t command,
u_int32_t arg0, u_int32_t arg1,
u_int32_t arg2, u_int32_t arg3);
static int aac_sa_get_mailbox(struct aac_softc *sc, int mb);
static void aac_sa_set_interrupts(struct aac_softc *sc, int enable);
const struct aac_interface aac_sa_interface = {
aac_sa_get_fwstatus,
aac_sa_qnotify,
aac_sa_get_istatus,
aac_sa_clear_istatus,
aac_sa_set_mailbox,
aac_sa_get_mailbox,
aac_sa_set_interrupts,
NULL, NULL, NULL
};
/* i960Rx interface */
static int aac_rx_get_fwstatus(struct aac_softc *sc);
static void aac_rx_qnotify(struct aac_softc *sc, int qbit);
static int aac_rx_get_istatus(struct aac_softc *sc);
static void aac_rx_clear_istatus(struct aac_softc *sc, int mask);
static void aac_rx_set_mailbox(struct aac_softc *sc, u_int32_t command,
u_int32_t arg0, u_int32_t arg1,
u_int32_t arg2, u_int32_t arg3);
static int aac_rx_get_mailbox(struct aac_softc *sc, int mb);
static void aac_rx_set_interrupts(struct aac_softc *sc, int enable);
static int aac_rx_send_command(struct aac_softc *sc, struct aac_command *cm);
static int aac_rx_get_outb_queue(struct aac_softc *sc);
static void aac_rx_set_outb_queue(struct aac_softc *sc, int index);
const struct aac_interface aac_rx_interface = {
aac_rx_get_fwstatus,
aac_rx_qnotify,
aac_rx_get_istatus,
aac_rx_clear_istatus,
aac_rx_set_mailbox,
aac_rx_get_mailbox,
aac_rx_set_interrupts,
aac_rx_send_command,
aac_rx_get_outb_queue,
aac_rx_set_outb_queue
};
/* Rocket/MIPS interface */
static int aac_rkt_get_fwstatus(struct aac_softc *sc);
static void aac_rkt_qnotify(struct aac_softc *sc, int qbit);
static int aac_rkt_get_istatus(struct aac_softc *sc);
static void aac_rkt_clear_istatus(struct aac_softc *sc, int mask);
static void aac_rkt_set_mailbox(struct aac_softc *sc, u_int32_t command,
u_int32_t arg0, u_int32_t arg1,
u_int32_t arg2, u_int32_t arg3);
static int aac_rkt_get_mailbox(struct aac_softc *sc, int mb);
static void aac_rkt_set_interrupts(struct aac_softc *sc, int enable);
static int aac_rkt_send_command(struct aac_softc *sc, struct aac_command *cm);
static int aac_rkt_get_outb_queue(struct aac_softc *sc);
static void aac_rkt_set_outb_queue(struct aac_softc *sc, int index);
const struct aac_interface aac_rkt_interface = {
aac_rkt_get_fwstatus,
aac_rkt_qnotify,
aac_rkt_get_istatus,
aac_rkt_clear_istatus,
aac_rkt_set_mailbox,
aac_rkt_get_mailbox,
aac_rkt_set_interrupts,
aac_rkt_send_command,
aac_rkt_get_outb_queue,
aac_rkt_set_outb_queue
};
/* Debugging and Diagnostics */
static void aac_describe_controller(struct aac_softc *sc);
static const char *aac_describe_code(const struct aac_code_lookup *table,
u_int32_t code);
/* Management Interface */
static d_open_t aac_open;
static d_ioctl_t aac_ioctl;
static d_poll_t aac_poll;
static void aac_cdevpriv_dtor(void *arg);
static int aac_ioctl_sendfib(struct aac_softc *sc, caddr_t ufib);
static int aac_ioctl_send_raw_srb(struct aac_softc *sc, caddr_t arg);
static void aac_handle_aif(struct aac_softc *sc,
struct aac_fib *fib);
static int aac_rev_check(struct aac_softc *sc, caddr_t udata);
static int aac_open_aif(struct aac_softc *sc, caddr_t arg);
static int aac_close_aif(struct aac_softc *sc, caddr_t arg);
static int aac_getnext_aif(struct aac_softc *sc, caddr_t arg);
static int aac_return_aif(struct aac_softc *sc,
struct aac_fib_context *ctx, caddr_t uptr);
static int aac_query_disk(struct aac_softc *sc, caddr_t uptr);
static int aac_get_pci_info(struct aac_softc *sc, caddr_t uptr);
static int aac_supported_features(struct aac_softc *sc, caddr_t uptr);
static void aac_ioctl_event(struct aac_softc *sc,
struct aac_event *event, void *arg);
static struct aac_mntinforesp *
aac_get_container_info(struct aac_softc *sc, struct aac_fib *fib, int cid);
static struct cdevsw aac_cdevsw = {
.d_version = D_VERSION,
.d_flags = 0,
.d_open = aac_open,
.d_ioctl = aac_ioctl,
.d_poll = aac_poll,
.d_name = "aac",
};
static MALLOC_DEFINE(M_AACBUF, "aacbuf", "Buffers for the AAC driver");
/* sysctl node */
SYSCTL_NODE(_hw, OID_AUTO, aac, CTLFLAG_RD | CTLFLAG_MPSAFE, 0,
"AAC driver parameters");
/*
* Device Interface
*/
/*
* Initialize the controller and softc
*/
int
aac_attach(struct aac_softc *sc)
{
int error, unit;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
/*
* Initialize per-controller queues.
*/
aac_initq_free(sc);
aac_initq_ready(sc);
aac_initq_busy(sc);
aac_initq_bio(sc);
/*
* Initialize command-completion task.
*/
TASK_INIT(&sc->aac_task_complete, 0, aac_complete, sc);
/* mark controller as suspended until we get ourselves organised */
sc->aac_state |= AAC_STATE_SUSPEND;
/*
* Check that the firmware on the card is supported.
*/
if ((error = aac_check_firmware(sc)) != 0)
return(error);
/*
* Initialize locks
*/
mtx_init(&sc->aac_aifq_lock, "AAC AIF lock", NULL, MTX_DEF);
mtx_init(&sc->aac_io_lock, "AAC I/O lock", NULL, MTX_DEF);
mtx_init(&sc->aac_container_lock, "AAC container lock", NULL, MTX_DEF);
TAILQ_INIT(&sc->aac_container_tqh);
TAILQ_INIT(&sc->aac_ev_cmfree);
/* Initialize the clock daemon callout. */
callout_init_mtx(&sc->aac_daemontime, &sc->aac_io_lock, 0);
/*
* Initialize the adapter.
*/
if ((error = aac_alloc(sc)) != 0)
return(error);
if ((error = aac_init(sc)) != 0)
return(error);
/*
* Allocate and connect our interrupt.
*/
if ((error = aac_setup_intr(sc)) != 0)
return(error);
/*
* Print a little information about the controller.
*/
aac_describe_controller(sc);
/*
* Add sysctls.
*/
SYSCTL_ADD_INT(device_get_sysctl_ctx(sc->aac_dev),
SYSCTL_CHILDREN(device_get_sysctl_tree(sc->aac_dev)),
OID_AUTO, "firmware_build", CTLFLAG_RD,
&sc->aac_revision.buildNumber, 0,
"firmware build number");
/*
* Register to probe our containers later.
*/
sc->aac_ich.ich_func = aac_startup;
sc->aac_ich.ich_arg = sc;
if (config_intrhook_establish(&sc->aac_ich) != 0) {
device_printf(sc->aac_dev,
"can't establish configuration hook\n");
return(ENXIO);
}
/*
* Make the control device.
*/
unit = device_get_unit(sc->aac_dev);
sc->aac_dev_t = make_dev(&aac_cdevsw, unit, UID_ROOT, GID_OPERATOR,
0640, "aac%d", unit);
(void)make_dev_alias(sc->aac_dev_t, "afa%d", unit);
(void)make_dev_alias(sc->aac_dev_t, "hpn%d", unit);
sc->aac_dev_t->si_drv1 = sc;
/* Create the AIF thread */
if (kproc_create((void(*)(void *))aac_command_thread, sc,
&sc->aifthread, 0, 0, "aac%daif", unit))
panic("Could not create AIF thread");
/* Register the shutdown method to only be called post-dump */
if ((sc->eh = EVENTHANDLER_REGISTER(shutdown_final, aac_shutdown,
sc->aac_dev, SHUTDOWN_PRI_DEFAULT)) == NULL)
device_printf(sc->aac_dev,
"shutdown event registration failed\n");
/* Register with CAM for the non-DASD devices */
if ((sc->flags & AAC_FLAGS_ENABLE_CAM) != 0) {
TAILQ_INIT(&sc->aac_sim_tqh);
aac_get_bus_info(sc);
}
mtx_lock(&sc->aac_io_lock);
callout_reset(&sc->aac_daemontime, 60 * hz, aac_daemon, sc);
mtx_unlock(&sc->aac_io_lock);
return(0);
}
static void
aac_daemon(void *arg)
{
struct timeval tv;
struct aac_softc *sc;
struct aac_fib *fib;
sc = arg;
mtx_assert(&sc->aac_io_lock, MA_OWNED);
if (callout_pending(&sc->aac_daemontime) ||
callout_active(&sc->aac_daemontime) == 0)
return;
getmicrotime(&tv);
aac_alloc_sync_fib(sc, &fib);
*(uint32_t *)fib->data = tv.tv_sec;
aac_sync_fib(sc, SendHostTime, 0, fib, sizeof(uint32_t));
aac_release_sync_fib(sc);
callout_schedule(&sc->aac_daemontime, 30 * 60 * hz);
}
void
aac_add_event(struct aac_softc *sc, struct aac_event *event)
{
switch (event->ev_type & AAC_EVENT_MASK) {
case AAC_EVENT_CMFREE:
TAILQ_INSERT_TAIL(&sc->aac_ev_cmfree, event, ev_links);
break;
default:
device_printf(sc->aac_dev, "aac_add event: unknown event %d\n",
event->ev_type);
break;
}
}
/*
* Request information of container #cid
*/
static struct aac_mntinforesp *
aac_get_container_info(struct aac_softc *sc, struct aac_fib *fib, int cid)
{
struct aac_mntinfo *mi;
mi = (struct aac_mntinfo *)&fib->data[0];
/* use 64-bit LBA if enabled */
mi->Command = (sc->flags & AAC_FLAGS_LBA_64BIT) ?
VM_NameServe64 : VM_NameServe;
mi->MntType = FT_FILESYS;
mi->MntCount = cid;
if (aac_sync_fib(sc, ContainerCommand, 0, fib,
sizeof(struct aac_mntinfo))) {
device_printf(sc->aac_dev, "Error probing container %d\n", cid);
return (NULL);
}
return ((struct aac_mntinforesp *)&fib->data[0]);
}
/*
* Probe for containers, create disks.
*/
static void
aac_startup(void *arg)
{
struct aac_softc *sc;
struct aac_fib *fib;
struct aac_mntinforesp *mir;
int count = 0, i = 0;
sc = (struct aac_softc *)arg;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
mtx_lock(&sc->aac_io_lock);
aac_alloc_sync_fib(sc, &fib);
/* loop over possible containers */
do {
if ((mir = aac_get_container_info(sc, fib, i)) == NULL)
continue;
if (i == 0)
count = mir->MntRespCount;
aac_add_container(sc, mir, 0);
i++;
} while ((i < count) && (i < AAC_MAX_CONTAINERS));
aac_release_sync_fib(sc);
mtx_unlock(&sc->aac_io_lock);
/* mark the controller up */
sc->aac_state &= ~AAC_STATE_SUSPEND;
/* poke the bus to actually attach the child devices */
if (bus_generic_attach(sc->aac_dev))
device_printf(sc->aac_dev, "bus_generic_attach failed\n");
/* disconnect ourselves from the intrhook chain */
config_intrhook_disestablish(&sc->aac_ich);
/* enable interrupts now */
AAC_UNMASK_INTERRUPTS(sc);
}
/*
* Create a device to represent a new container
*/
static void
aac_add_container(struct aac_softc *sc, struct aac_mntinforesp *mir, int f)
{
struct aac_container *co;
device_t child;
/*
* Check container volume type for validity. Note that many of
* the possible types may never show up.
*/
if ((mir->Status == ST_OK) && (mir->MntTable[0].VolType != CT_NONE)) {
co = (struct aac_container *)malloc(sizeof *co, M_AACBUF,
M_NOWAIT | M_ZERO);
if (co == NULL)
panic("Out of memory?!");
fwprintf(sc, HBA_FLAGS_DBG_INIT_B, "id %x name '%.16s' size %u type %d",
mir->MntTable[0].ObjectId,
mir->MntTable[0].FileSystemName,
mir->MntTable[0].Capacity, mir->MntTable[0].VolType);
if ((child = device_add_child(sc->aac_dev, "aacd", -1)) == NULL)
device_printf(sc->aac_dev, "device_add_child failed\n");
else
device_set_ivars(child, co);
device_set_desc(child, aac_describe_code(aac_container_types,
mir->MntTable[0].VolType));
co->co_disk = child;
co->co_found = f;
bcopy(&mir->MntTable[0], &co->co_mntobj,
sizeof(struct aac_mntobj));
mtx_lock(&sc->aac_container_lock);
TAILQ_INSERT_TAIL(&sc->aac_container_tqh, co, co_link);
mtx_unlock(&sc->aac_container_lock);
}
}
/*
* Allocate resources associated with (sc)
*/
static int
aac_alloc(struct aac_softc *sc)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
/*
* Create DMA tag for mapping buffers into controller-addressable space.
*/
if (bus_dma_tag_create(sc->aac_parent_dmat, /* parent */
1, 0, /* algnmnt, boundary */
(sc->flags & AAC_FLAGS_SG_64BIT) ?
BUS_SPACE_MAXADDR :
BUS_SPACE_MAXADDR_32BIT, /* lowaddr */
BUS_SPACE_MAXADDR, /* highaddr */
NULL, NULL, /* filter, filterarg */
sc->aac_max_sectors << 9, /* maxsize */
sc->aac_sg_tablesize, /* nsegments */
BUS_SPACE_MAXSIZE_32BIT, /* maxsegsize */
BUS_DMA_ALLOCNOW, /* flags */
busdma_lock_mutex, /* lockfunc */
&sc->aac_io_lock, /* lockfuncarg */
&sc->aac_buffer_dmat)) {
device_printf(sc->aac_dev, "can't allocate buffer DMA tag\n");
return (ENOMEM);
}
/*
* Create DMA tag for mapping FIBs into controller-addressable space..
*/
if (bus_dma_tag_create(sc->aac_parent_dmat, /* parent */
1, 0, /* algnmnt, boundary */
(sc->flags & AAC_FLAGS_4GB_WINDOW) ?
BUS_SPACE_MAXADDR_32BIT :
0x7fffffff, /* lowaddr */
BUS_SPACE_MAXADDR, /* highaddr */
NULL, NULL, /* filter, filterarg */
sc->aac_max_fibs_alloc *
sc->aac_max_fib_size, /* maxsize */
1, /* nsegments */
sc->aac_max_fibs_alloc *
sc->aac_max_fib_size, /* maxsize */
0, /* flags */
NULL, NULL, /* No locking needed */
&sc->aac_fib_dmat)) {
device_printf(sc->aac_dev, "can't allocate FIB DMA tag\n");
return (ENOMEM);
}
/*
* Create DMA tag for the common structure and allocate it.
*/
if (bus_dma_tag_create(sc->aac_parent_dmat, /* parent */
1, 0, /* algnmnt, boundary */
(sc->flags & AAC_FLAGS_4GB_WINDOW) ?
BUS_SPACE_MAXADDR_32BIT :
0x7fffffff, /* lowaddr */
BUS_SPACE_MAXADDR, /* highaddr */
NULL, NULL, /* filter, filterarg */
8192 + sizeof(struct aac_common), /* maxsize */
1, /* nsegments */
BUS_SPACE_MAXSIZE_32BIT, /* maxsegsize */
0, /* flags */
NULL, NULL, /* No locking needed */
&sc->aac_common_dmat)) {
device_printf(sc->aac_dev,
"can't allocate common structure DMA tag\n");
return (ENOMEM);
}
if (bus_dmamem_alloc(sc->aac_common_dmat, (void **)&sc->aac_common,
BUS_DMA_NOWAIT, &sc->aac_common_dmamap)) {
device_printf(sc->aac_dev, "can't allocate common structure\n");
return (ENOMEM);
}
/*
* Work around a bug in the 2120 and 2200 that cannot DMA commands
* below address 8192 in physical memory.
* XXX If the padding is not needed, can it be put to use instead
* of ignored?
*/
(void)bus_dmamap_load(sc->aac_common_dmat, sc->aac_common_dmamap,
sc->aac_common, 8192 + sizeof(*sc->aac_common),
aac_common_map, sc, 0);
if (sc->aac_common_busaddr < 8192) {
sc->aac_common = (struct aac_common *)
((uint8_t *)sc->aac_common + 8192);
sc->aac_common_busaddr += 8192;
}
bzero(sc->aac_common, sizeof(*sc->aac_common));
/* Allocate some FIBs and associated command structs */
TAILQ_INIT(&sc->aac_fibmap_tqh);
sc->aac_commands = malloc(sc->aac_max_fibs * sizeof(struct aac_command),
M_AACBUF, M_WAITOK|M_ZERO);
while (sc->total_fibs < sc->aac_max_fibs) {
if (aac_alloc_commands(sc) != 0)
break;
}
if (sc->total_fibs == 0)
return (ENOMEM);
return (0);
}
/*
* Free all of the resources associated with (sc)
*
* Should not be called if the controller is active.
*/
void
aac_free(struct aac_softc *sc)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
/* remove the control device */
if (sc->aac_dev_t != NULL)
destroy_dev(sc->aac_dev_t);
/* throw away any FIB buffers, discard the FIB DMA tag */
aac_free_commands(sc);
if (sc->aac_fib_dmat)
bus_dma_tag_destroy(sc->aac_fib_dmat);
free(sc->aac_commands, M_AACBUF);
/* destroy the common area */
if (sc->aac_common) {
bus_dmamap_unload(sc->aac_common_dmat, sc->aac_common_dmamap);
bus_dmamem_free(sc->aac_common_dmat, sc->aac_common,
sc->aac_common_dmamap);
}
if (sc->aac_common_dmat)
bus_dma_tag_destroy(sc->aac_common_dmat);
/* disconnect the interrupt handler */
if (sc->aac_intr)
bus_teardown_intr(sc->aac_dev, sc->aac_irq, sc->aac_intr);
if (sc->aac_irq != NULL) {
bus_release_resource(sc->aac_dev, SYS_RES_IRQ,
rman_get_rid(sc->aac_irq), sc->aac_irq);
pci_release_msi(sc->aac_dev);
}
/* destroy data-transfer DMA tag */
if (sc->aac_buffer_dmat)
bus_dma_tag_destroy(sc->aac_buffer_dmat);
/* destroy the parent DMA tag */
if (sc->aac_parent_dmat)
bus_dma_tag_destroy(sc->aac_parent_dmat);
/* release the register window mapping */
if (sc->aac_regs_res0 != NULL)
bus_release_resource(sc->aac_dev, SYS_RES_MEMORY,
rman_get_rid(sc->aac_regs_res0), sc->aac_regs_res0);
if (sc->aac_hwif == AAC_HWIF_NARK && sc->aac_regs_res1 != NULL)
bus_release_resource(sc->aac_dev, SYS_RES_MEMORY,
rman_get_rid(sc->aac_regs_res1), sc->aac_regs_res1);
}
/*
* Disconnect from the controller completely, in preparation for unload.
*/
int
aac_detach(device_t dev)
{
struct aac_softc *sc;
struct aac_container *co;
struct aac_sim *sim;
int error;
sc = device_get_softc(dev);
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
callout_drain(&sc->aac_daemontime);
mtx_lock(&sc->aac_io_lock);
while (sc->aifflags & AAC_AIFFLAGS_RUNNING) {
sc->aifflags |= AAC_AIFFLAGS_EXIT;
wakeup(sc->aifthread);
msleep(sc->aac_dev, &sc->aac_io_lock, PUSER, "aacdch", 0);
}
mtx_unlock(&sc->aac_io_lock);
KASSERT((sc->aifflags & AAC_AIFFLAGS_RUNNING) == 0,
("%s: invalid detach state", __func__));
/* Remove the child containers */
while ((co = TAILQ_FIRST(&sc->aac_container_tqh)) != NULL) {
error = device_delete_child(dev, co->co_disk);
if (error)
return (error);
TAILQ_REMOVE(&sc->aac_container_tqh, co, co_link);
free(co, M_AACBUF);
}
/* Remove the CAM SIMs */
while ((sim = TAILQ_FIRST(&sc->aac_sim_tqh)) != NULL) {
TAILQ_REMOVE(&sc->aac_sim_tqh, sim, sim_link);
error = device_delete_child(dev, sim->sim_dev);
if (error)
return (error);
free(sim, M_AACBUF);
}
if ((error = aac_shutdown(dev)))
return(error);
EVENTHANDLER_DEREGISTER(shutdown_final, sc->eh);
aac_free(sc);
mtx_destroy(&sc->aac_aifq_lock);
mtx_destroy(&sc->aac_io_lock);
mtx_destroy(&sc->aac_container_lock);
return(0);
}
/*
* Bring the controller down to a dormant state and detach all child devices.
*
* This function is called before detach or system shutdown.
*
* Note that we can assume that the bioq on the controller is empty, as we won't
* allow shutdown if any device is open.
*/
int
aac_shutdown(device_t dev)
{
struct aac_softc *sc;
struct aac_fib *fib;
struct aac_close_command *cc;
sc = device_get_softc(dev);
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
sc->aac_state |= AAC_STATE_SUSPEND;
/*
* Send a Container shutdown followed by a HostShutdown FIB to the
* controller to convince it that we don't want to talk to it anymore.
* We've been closed and all I/O completed already
*/
device_printf(sc->aac_dev, "shutting down controller...");
mtx_lock(&sc->aac_io_lock);
aac_alloc_sync_fib(sc, &fib);
cc = (struct aac_close_command *)&fib->data[0];
bzero(cc, sizeof(struct aac_close_command));
cc->Command = VM_CloseAll;
cc->ContainerId = 0xffffffff;
if (aac_sync_fib(sc, ContainerCommand, 0, fib,
sizeof(struct aac_close_command)))
printf("FAILED.\n");
else
printf("done\n");
#if 0
else {
fib->data[0] = 0;
/*
* XXX Issuing this command to the controller makes it shut down
* but also keeps it from coming back up without a reset of the
* PCI bus. This is not desirable if you are just unloading the
* driver module with the intent to reload it later.
*/
if (aac_sync_fib(sc, FsaHostShutdown, AAC_FIBSTATE_SHUTDOWN,
fib, 1)) {
printf("FAILED.\n");
} else {
printf("done.\n");
}
}
#endif
AAC_MASK_INTERRUPTS(sc);
aac_release_sync_fib(sc);
mtx_unlock(&sc->aac_io_lock);
return(0);
}
/*
* Bring the controller to a quiescent state, ready for system suspend.
*/
int
aac_suspend(device_t dev)
{
struct aac_softc *sc;
sc = device_get_softc(dev);
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
sc->aac_state |= AAC_STATE_SUSPEND;
AAC_MASK_INTERRUPTS(sc);
return(0);
}
/*
* Bring the controller back to a state ready for operation.
*/
int
aac_resume(device_t dev)
{
struct aac_softc *sc;
sc = device_get_softc(dev);
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
sc->aac_state &= ~AAC_STATE_SUSPEND;
AAC_UNMASK_INTERRUPTS(sc);
return(0);
}
/*
* Interrupt handler for NEW_COMM interface.
*/
void
aac_new_intr(void *arg)
{
struct aac_softc *sc;
u_int32_t index, fast;
struct aac_command *cm;
struct aac_fib *fib;
int i;
sc = (struct aac_softc *)arg;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
mtx_lock(&sc->aac_io_lock);
while (1) {
index = AAC_GET_OUTB_QUEUE(sc);
if (index == 0xffffffff)
index = AAC_GET_OUTB_QUEUE(sc);
if (index == 0xffffffff)
break;
if (index & 2) {
if (index == 0xfffffffe) {
/* XXX This means that the controller wants
* more work. Ignore it for now.
*/
continue;
}
/* AIF */
fib = (struct aac_fib *)malloc(sizeof *fib, M_AACBUF,
M_NOWAIT | M_ZERO);
if (fib == NULL) {
/* If we're really this short on memory,
* hopefully breaking out of the handler will
* allow something to get freed. This
* actually sucks a whole lot.
*/
break;
}
index &= ~2;
for (i = 0; i < sizeof(struct aac_fib)/4; ++i)
((u_int32_t *)fib)[i] = AAC_MEM1_GETREG4(sc, index + i*4);
aac_handle_aif(sc, fib);
free(fib, M_AACBUF);
/*
* AIF memory is owned by the adapter, so let it
* know that we are done with it.
*/
AAC_SET_OUTB_QUEUE(sc, index);
AAC_CLEAR_ISTATUS(sc, AAC_DB_RESPONSE_READY);
} else {
fast = index & 1;
cm = sc->aac_commands + (index >> 2);
fib = cm->cm_fib;
if (fast) {
fib->Header.XferState |= AAC_FIBSTATE_DONEADAP;
*((u_int32_t *)(fib->data)) = AAC_ERROR_NORMAL;
}
aac_remove_busy(cm);
aac_unmap_command(cm);
cm->cm_flags |= AAC_CMD_COMPLETED;
/* is there a completion handler? */
if (cm->cm_complete != NULL) {
cm->cm_complete(cm);
} else {
/* assume that someone is sleeping on this
* command
*/
wakeup(cm);
}
sc->flags &= ~AAC_QUEUE_FRZN;
}
}
/* see if we can start some more I/O */
if ((sc->flags & AAC_QUEUE_FRZN) == 0)
aac_startio(sc);
mtx_unlock(&sc->aac_io_lock);
}
/*
* Interrupt filter for !NEW_COMM interface.
*/
int
aac_filter(void *arg)
{
struct aac_softc *sc;
u_int16_t reason;
sc = (struct aac_softc *)arg;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
/*
* Read the status register directly. This is faster than taking the
* driver lock and reading the queues directly. It also saves having
* to turn parts of the driver lock into a spin mutex, which would be
* ugly.
*/
reason = AAC_GET_ISTATUS(sc);
AAC_CLEAR_ISTATUS(sc, reason);
/* handle completion processing */
if (reason & AAC_DB_RESPONSE_READY)
taskqueue_enqueue(taskqueue_fast, &sc->aac_task_complete);
/* controller wants to talk to us */
if (reason & (AAC_DB_PRINTF | AAC_DB_COMMAND_READY)) {
/*
* XXX Make sure that we don't get fooled by strange messages
* that start with a NULL.
*/
if ((reason & AAC_DB_PRINTF) &&
(sc->aac_common->ac_printf[0] == 0))
sc->aac_common->ac_printf[0] = 32;
/*
* This might miss doing the actual wakeup. However, the
* msleep that this is waking up has a timeout, so it will
* wake up eventually. AIFs and printfs are low enough
* priority that they can handle hanging out for a few seconds
* if needed.
*/
wakeup(sc->aifthread);
}
return (FILTER_HANDLED);
}
/*
* Command Processing
*/
/*
* Start as much queued I/O as possible on the controller
*/
void
aac_startio(struct aac_softc *sc)
{
struct aac_command *cm;
int error;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
for (;;) {
/*
* This flag might be set if the card is out of resources.
* Checking it here prevents an infinite loop of deferrals.
*/
if (sc->flags & AAC_QUEUE_FRZN)
break;
/*
* Try to get a command that's been put off for lack of
* resources
*/
cm = aac_dequeue_ready(sc);
/*
* Try to build a command off the bio queue (ignore error
* return)
*/
if (cm == NULL)
aac_bio_command(sc, &cm);
/* nothing to do? */
if (cm == NULL)
break;
/* don't map more than once */
if (cm->cm_flags & AAC_CMD_MAPPED)
panic("aac: command %p already mapped", cm);
/*
* Set up the command to go to the controller. If there are no
* data buffers associated with the command then it can bypass
* busdma.
*/
if (cm->cm_datalen != 0) {
if (cm->cm_flags & AAC_REQ_BIO)
error = bus_dmamap_load_bio(
sc->aac_buffer_dmat, cm->cm_datamap,
(struct bio *)cm->cm_private,
aac_map_command_sg, cm, 0);
else
error = bus_dmamap_load(sc->aac_buffer_dmat,
cm->cm_datamap, cm->cm_data,
cm->cm_datalen, aac_map_command_sg, cm, 0);
if (error == EINPROGRESS) {
fwprintf(sc, HBA_FLAGS_DBG_COMM_B, "freezing queue\n");
sc->flags |= AAC_QUEUE_FRZN;
} else if (error != 0)
panic("aac_startio: unexpected error %d from "
"busdma", error);
} else
aac_map_command_sg(cm, NULL, 0, 0);
}
}
/*
* Handle notification of one or more FIBs coming from the controller.
*/
static void
aac_command_thread(struct aac_softc *sc)
{
struct aac_fib *fib;
u_int32_t fib_size;
int size, retval;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
mtx_lock(&sc->aac_io_lock);
sc->aifflags = AAC_AIFFLAGS_RUNNING;
while ((sc->aifflags & AAC_AIFFLAGS_EXIT) == 0) {
retval = 0;
if ((sc->aifflags & AAC_AIFFLAGS_PENDING) == 0)
retval = msleep(sc->aifthread, &sc->aac_io_lock, PRIBIO,
"aifthd", AAC_PERIODIC_INTERVAL * hz);
/*
* First see if any FIBs need to be allocated. This needs
* to be called without the driver lock because contigmalloc
* can sleep.
*/
if ((sc->aifflags & AAC_AIFFLAGS_ALLOCFIBS) != 0) {
mtx_unlock(&sc->aac_io_lock);
aac_alloc_commands(sc);
mtx_lock(&sc->aac_io_lock);
sc->aifflags &= ~AAC_AIFFLAGS_ALLOCFIBS;
aac_startio(sc);
}
/*
* While we're here, check to see if any commands are stuck.
* This is pretty low-priority, so it's ok if it doesn't
* always fire.
*/
if (retval == EWOULDBLOCK)
aac_timeout(sc);
/* Check the hardware printf message buffer */
if (sc->aac_common->ac_printf[0] != 0)
aac_print_printf(sc);
/* Also check to see if the adapter has a command for us. */
if (sc->flags & AAC_FLAGS_NEW_COMM)
continue;
for (;;) {
if (aac_dequeue_fib(sc, AAC_HOST_NORM_CMD_QUEUE,
&fib_size, &fib))
break;
AAC_PRINT_FIB(sc, fib);
switch (fib->Header.Command) {
case AifRequest:
aac_handle_aif(sc, fib);
break;
default:
device_printf(sc->aac_dev, "unknown command "
"from controller\n");
break;
}
if ((fib->Header.XferState == 0) ||
(fib->Header.StructType != AAC_FIBTYPE_TFIB)) {
break;
}
/* Return the AIF to the controller. */
if (fib->Header.XferState & AAC_FIBSTATE_FROMADAP) {
fib->Header.XferState |= AAC_FIBSTATE_DONEHOST;
*(AAC_FSAStatus*)fib->data = ST_OK;
/* XXX Compute the Size field? */
size = fib->Header.Size;
if (size > sizeof(struct aac_fib)) {
size = sizeof(struct aac_fib);
fib->Header.Size = size;
}
/*
* Since we did not generate this command, it
* cannot go through the normal
* enqueue->startio chain.
*/
aac_enqueue_response(sc,
AAC_ADAP_NORM_RESP_QUEUE,
fib);
}
}
}
sc->aifflags &= ~AAC_AIFFLAGS_RUNNING;
mtx_unlock(&sc->aac_io_lock);
wakeup(sc->aac_dev);
kproc_exit(0);
}
/*
* Process completed commands.
*/
static void
aac_complete(void *context, int pending)
{
struct aac_softc *sc;
struct aac_command *cm;
struct aac_fib *fib;
u_int32_t fib_size;
sc = (struct aac_softc *)context;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
mtx_lock(&sc->aac_io_lock);
/* pull completed commands off the queue */
for (;;) {
/* look for completed FIBs on our queue */
if (aac_dequeue_fib(sc, AAC_HOST_NORM_RESP_QUEUE, &fib_size,
&fib))
break; /* nothing to do */
/* get the command, unmap and hand off for processing */
cm = sc->aac_commands + fib->Header.SenderData;
if (cm == NULL) {
AAC_PRINT_FIB(sc, fib);
break;
}
if ((cm->cm_flags & AAC_CMD_TIMEDOUT) != 0)
device_printf(sc->aac_dev,
"COMMAND %p COMPLETED AFTER %d SECONDS\n",
cm, (int)(time_uptime-cm->cm_timestamp));
aac_remove_busy(cm);
aac_unmap_command(cm);
cm->cm_flags |= AAC_CMD_COMPLETED;
/* is there a completion handler? */
if (cm->cm_complete != NULL) {
cm->cm_complete(cm);
} else {
/* assume that someone is sleeping on this command */
wakeup(cm);
}
}
/* see if we can start some more I/O */
sc->flags &= ~AAC_QUEUE_FRZN;
aac_startio(sc);
mtx_unlock(&sc->aac_io_lock);
}
/*
* Handle a bio submitted from a disk device.
*/
void
aac_submit_bio(struct bio *bp)
{
struct aac_disk *ad;
struct aac_softc *sc;
ad = (struct aac_disk *)bp->bio_disk->d_drv1;
sc = ad->ad_controller;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
/* queue the BIO and try to get some work done */
aac_enqueue_bio(sc, bp);
aac_startio(sc);
}
/*
* Get a bio and build a command to go with it.
*/
static int
aac_bio_command(struct aac_softc *sc, struct aac_command **cmp)
{
struct aac_command *cm;
struct aac_fib *fib;
struct aac_disk *ad;
struct bio *bp;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
/* get the resources we will need */
cm = NULL;
bp = NULL;
if (aac_alloc_command(sc, &cm)) /* get a command */
goto fail;
if ((bp = aac_dequeue_bio(sc)) == NULL)
goto fail;
/* fill out the command */
cm->cm_datalen = bp->bio_bcount;
cm->cm_complete = aac_bio_complete;
cm->cm_flags = AAC_REQ_BIO;
cm->cm_private = bp;
cm->cm_timestamp = time_uptime;
/* build the FIB */
fib = cm->cm_fib;
fib->Header.Size = sizeof(struct aac_fib_header);
fib->Header.XferState =
AAC_FIBSTATE_HOSTOWNED |
AAC_FIBSTATE_INITIALISED |
AAC_FIBSTATE_EMPTY |
AAC_FIBSTATE_FROMHOST |
AAC_FIBSTATE_REXPECTED |
AAC_FIBSTATE_NORM |
AAC_FIBSTATE_ASYNC |
AAC_FIBSTATE_FAST_RESPONSE;
/* build the read/write request */
ad = (struct aac_disk *)bp->bio_disk->d_drv1;
if (sc->flags & AAC_FLAGS_RAW_IO) {
struct aac_raw_io *raw;
raw = (struct aac_raw_io *)&fib->data[0];
fib->Header.Command = RawIo;
raw->BlockNumber = (u_int64_t)bp->bio_pblkno;
raw->ByteCount = bp->bio_bcount;
raw->ContainerId = ad->ad_container->co_mntobj.ObjectId;
raw->BpTotal = 0;
raw->BpComplete = 0;
fib->Header.Size += sizeof(struct aac_raw_io);
cm->cm_sgtable = (struct aac_sg_table *)&raw->SgMapRaw;
if (bp->bio_cmd == BIO_READ) {
raw->Flags = 1;
cm->cm_flags |= AAC_CMD_DATAIN;
} else {
raw->Flags = 0;
cm->cm_flags |= AAC_CMD_DATAOUT;
}
} else if ((sc->flags & AAC_FLAGS_SG_64BIT) == 0) {
fib->Header.Command = ContainerCommand;
if (bp->bio_cmd == BIO_READ) {
struct aac_blockread *br;
br = (struct aac_blockread *)&fib->data[0];
br->Command = VM_CtBlockRead;
br->ContainerId = ad->ad_container->co_mntobj.ObjectId;
br->BlockNumber = bp->bio_pblkno;
br->ByteCount = bp->bio_bcount;
fib->Header.Size += sizeof(struct aac_blockread);
cm->cm_sgtable = &br->SgMap;
cm->cm_flags |= AAC_CMD_DATAIN;
} else {
struct aac_blockwrite *bw;
bw = (struct aac_blockwrite *)&fib->data[0];
bw->Command = VM_CtBlockWrite;
bw->ContainerId = ad->ad_container->co_mntobj.ObjectId;
bw->BlockNumber = bp->bio_pblkno;
bw->ByteCount = bp->bio_bcount;
bw->Stable = CUNSTABLE;
fib->Header.Size += sizeof(struct aac_blockwrite);
cm->cm_flags |= AAC_CMD_DATAOUT;
cm->cm_sgtable = &bw->SgMap;
}
} else {
fib->Header.Command = ContainerCommand64;
if (bp->bio_cmd == BIO_READ) {
struct aac_blockread64 *br;
br = (struct aac_blockread64 *)&fib->data[0];
br->Command = VM_CtHostRead64;
br->ContainerId = ad->ad_container->co_mntobj.ObjectId;
br->SectorCount = bp->bio_bcount / AAC_BLOCK_SIZE;
br->BlockNumber = bp->bio_pblkno;
br->Pad = 0;
br->Flags = 0;
fib->Header.Size += sizeof(struct aac_blockread64);
cm->cm_flags |= AAC_CMD_DATAIN;
cm->cm_sgtable = (struct aac_sg_table *)&br->SgMap64;
} else {
struct aac_blockwrite64 *bw;
bw = (struct aac_blockwrite64 *)&fib->data[0];
bw->Command = VM_CtHostWrite64;
bw->ContainerId = ad->ad_container->co_mntobj.ObjectId;
bw->SectorCount = bp->bio_bcount / AAC_BLOCK_SIZE;
bw->BlockNumber = bp->bio_pblkno;
bw->Pad = 0;
bw->Flags = 0;
fib->Header.Size += sizeof(struct aac_blockwrite64);
cm->cm_flags |= AAC_CMD_DATAOUT;
cm->cm_sgtable = (struct aac_sg_table *)&bw->SgMap64;
}
}
*cmp = cm;
return(0);
fail:
if (bp != NULL)
aac_enqueue_bio(sc, bp);
if (cm != NULL)
aac_release_command(cm);
return(ENOMEM);
}
/*
* Handle a bio-instigated command that has been completed.
*/
static void
aac_bio_complete(struct aac_command *cm)
{
struct aac_blockread_response *brr;
struct aac_blockwrite_response *bwr;
struct bio *bp;
AAC_FSAStatus status;
/* fetch relevant status and then release the command */
bp = (struct bio *)cm->cm_private;
if (bp->bio_cmd == BIO_READ) {
brr = (struct aac_blockread_response *)&cm->cm_fib->data[0];
status = brr->Status;
} else {
bwr = (struct aac_blockwrite_response *)&cm->cm_fib->data[0];
status = bwr->Status;
}
aac_release_command(cm);
/* fix up the bio based on status */
if (status == ST_OK) {
bp->bio_resid = 0;
} else {
bp->bio_error = EIO;
bp->bio_flags |= BIO_ERROR;
}
aac_biodone(bp);
}
/*
* Submit a command to the controller, return when it completes.
* XXX This is very dangerous! If the card has gone out to lunch, we could
* be stuck here forever. At the same time, signals are not caught
* because there is a risk that a signal could wakeup the sleep before
* the card has a chance to complete the command. Since there is no way
* to cancel a command that is in progress, we can't protect against the
* card completing a command late and spamming the command and data
* memory. So, we are held hostage until the command completes.
*/
static int
aac_wait_command(struct aac_command *cm)
{
struct aac_softc *sc;
int error;
sc = cm->cm_sc;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
/* Put the command on the ready queue and get things going */
aac_enqueue_ready(cm);
aac_startio(sc);
error = msleep(cm, &sc->aac_io_lock, PRIBIO, "aacwait", 0);
return(error);
}
/*
*Command Buffer Management
*/
/*
* Allocate a command.
*/
int
aac_alloc_command(struct aac_softc *sc, struct aac_command **cmp)
{
struct aac_command *cm;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
if ((cm = aac_dequeue_free(sc)) == NULL) {
if (sc->total_fibs < sc->aac_max_fibs) {
mtx_lock(&sc->aac_io_lock);
sc->aifflags |= AAC_AIFFLAGS_ALLOCFIBS;
mtx_unlock(&sc->aac_io_lock);
wakeup(sc->aifthread);
}
return (EBUSY);
}
*cmp = cm;
return(0);
}
/*
* Release a command back to the freelist.
*/
void
aac_release_command(struct aac_command *cm)
{
struct aac_event *event;
struct aac_softc *sc;
sc = cm->cm_sc;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
/* (re)initialize the command/FIB */
cm->cm_datalen = 0;
cm->cm_sgtable = NULL;
cm->cm_flags = 0;
cm->cm_complete = NULL;
cm->cm_private = NULL;
cm->cm_queue = AAC_ADAP_NORM_CMD_QUEUE;
cm->cm_fib->Header.XferState = AAC_FIBSTATE_EMPTY;
cm->cm_fib->Header.StructType = AAC_FIBTYPE_TFIB;
cm->cm_fib->Header.Flags = 0;
cm->cm_fib->Header.SenderSize = cm->cm_sc->aac_max_fib_size;
/*
* These are duplicated in aac_start to cover the case where an
* intermediate stage may have destroyed them. They're left
* initialized here for debugging purposes only.
*/
cm->cm_fib->Header.ReceiverFibAddress = (u_int32_t)cm->cm_fibphys;
cm->cm_fib->Header.SenderData = 0;
aac_enqueue_free(cm);
if ((event = TAILQ_FIRST(&sc->aac_ev_cmfree)) != NULL) {
TAILQ_REMOVE(&sc->aac_ev_cmfree, event, ev_links);
event->ev_callback(sc, event, event->ev_arg);
}
}
/*
* Map helper for command/FIB allocation.
*/
static void
aac_map_command_helper(void *arg, bus_dma_segment_t *segs, int nseg, int error)
{
uint64_t *fibphys;
fibphys = (uint64_t *)arg;
*fibphys = segs[0].ds_addr;
}
/*
* Allocate and initialize commands/FIBs for this adapter.
*/
static int
aac_alloc_commands(struct aac_softc *sc)
{
struct aac_command *cm;
struct aac_fibmap *fm;
uint64_t fibphys;
int i, error;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
if (sc->total_fibs + sc->aac_max_fibs_alloc > sc->aac_max_fibs)
return (ENOMEM);
fm = malloc(sizeof(struct aac_fibmap), M_AACBUF, M_NOWAIT|M_ZERO);
if (fm == NULL)
return (ENOMEM);
/* allocate the FIBs in DMAable memory and load them */
if (bus_dmamem_alloc(sc->aac_fib_dmat, (void **)&fm->aac_fibs,
BUS_DMA_NOWAIT, &fm->aac_fibmap)) {
device_printf(sc->aac_dev,
"Not enough contiguous memory available.\n");
free(fm, M_AACBUF);
return (ENOMEM);
}
/* Ignore errors since this doesn't bounce */
(void)bus_dmamap_load(sc->aac_fib_dmat, fm->aac_fibmap, fm->aac_fibs,
sc->aac_max_fibs_alloc * sc->aac_max_fib_size,
aac_map_command_helper, &fibphys, 0);
/* initialize constant fields in the command structure */
bzero(fm->aac_fibs, sc->aac_max_fibs_alloc * sc->aac_max_fib_size);
for (i = 0; i < sc->aac_max_fibs_alloc; i++) {
cm = sc->aac_commands + sc->total_fibs;
fm->aac_commands = cm;
cm->cm_sc = sc;
cm->cm_fib = (struct aac_fib *)
((u_int8_t *)fm->aac_fibs + i*sc->aac_max_fib_size);
cm->cm_fibphys = fibphys + i*sc->aac_max_fib_size;
cm->cm_index = sc->total_fibs;
if ((error = bus_dmamap_create(sc->aac_buffer_dmat, 0,
&cm->cm_datamap)) != 0)
break;
mtx_lock(&sc->aac_io_lock);
aac_release_command(cm);
sc->total_fibs++;
mtx_unlock(&sc->aac_io_lock);
}
if (i > 0) {
mtx_lock(&sc->aac_io_lock);
TAILQ_INSERT_TAIL(&sc->aac_fibmap_tqh, fm, fm_link);
fwprintf(sc, HBA_FLAGS_DBG_COMM_B, "total_fibs= %d\n", sc->total_fibs);
mtx_unlock(&sc->aac_io_lock);
return (0);
}
bus_dmamap_unload(sc->aac_fib_dmat, fm->aac_fibmap);
bus_dmamem_free(sc->aac_fib_dmat, fm->aac_fibs, fm->aac_fibmap);
free(fm, M_AACBUF);
return (ENOMEM);
}
/*
* Free FIBs owned by this adapter.
*/
static void
aac_free_commands(struct aac_softc *sc)
{
struct aac_fibmap *fm;
struct aac_command *cm;
int i;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
while ((fm = TAILQ_FIRST(&sc->aac_fibmap_tqh)) != NULL) {
TAILQ_REMOVE(&sc->aac_fibmap_tqh, fm, fm_link);
/*
* We check against total_fibs to handle partially
* allocated blocks.
*/
for (i = 0; i < sc->aac_max_fibs_alloc && sc->total_fibs--; i++) {
cm = fm->aac_commands + i;
bus_dmamap_destroy(sc->aac_buffer_dmat, cm->cm_datamap);
}
bus_dmamap_unload(sc->aac_fib_dmat, fm->aac_fibmap);
bus_dmamem_free(sc->aac_fib_dmat, fm->aac_fibs, fm->aac_fibmap);
free(fm, M_AACBUF);
}
}
/*
* Command-mapping helper function - populate this command's s/g table.
*/
static void
aac_map_command_sg(void *arg, bus_dma_segment_t *segs, int nseg, int error)
{
struct aac_softc *sc;
struct aac_command *cm;
struct aac_fib *fib;
int i;
cm = (struct aac_command *)arg;
sc = cm->cm_sc;
fib = cm->cm_fib;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
/* copy into the FIB */
if (cm->cm_sgtable != NULL) {
if (fib->Header.Command == RawIo) {
struct aac_sg_tableraw *sg;
sg = (struct aac_sg_tableraw *)cm->cm_sgtable;
sg->SgCount = nseg;
for (i = 0; i < nseg; i++) {
sg->SgEntryRaw[i].SgAddress = segs[i].ds_addr;
sg->SgEntryRaw[i].SgByteCount = segs[i].ds_len;
sg->SgEntryRaw[i].Next = 0;
sg->SgEntryRaw[i].Prev = 0;
sg->SgEntryRaw[i].Flags = 0;
}
/* update the FIB size for the s/g count */
fib->Header.Size += nseg*sizeof(struct aac_sg_entryraw);
} else if ((cm->cm_sc->flags & AAC_FLAGS_SG_64BIT) == 0) {
struct aac_sg_table *sg;
sg = cm->cm_sgtable;
sg->SgCount = nseg;
for (i = 0; i < nseg; i++) {
sg->SgEntry[i].SgAddress = segs[i].ds_addr;
sg->SgEntry[i].SgByteCount = segs[i].ds_len;
}
/* update the FIB size for the s/g count */
fib->Header.Size += nseg*sizeof(struct aac_sg_entry);
} else {
struct aac_sg_table64 *sg;
sg = (struct aac_sg_table64 *)cm->cm_sgtable;
sg->SgCount = nseg;
for (i = 0; i < nseg; i++) {
sg->SgEntry64[i].SgAddress = segs[i].ds_addr;
sg->SgEntry64[i].SgByteCount = segs[i].ds_len;
}
/* update the FIB size for the s/g count */
fib->Header.Size += nseg*sizeof(struct aac_sg_entry64);
}
}
/* Fix up the address values in the FIB. Use the command array index
* instead of a pointer since these fields are only 32 bits. Shift
* the SenderFibAddress over to make room for the fast response bit
* and for the AIF bit
*/
cm->cm_fib->Header.SenderFibAddress = (cm->cm_index << 2);
cm->cm_fib->Header.ReceiverFibAddress = (u_int32_t)cm->cm_fibphys;
/* save a pointer to the command for speedy reverse-lookup */
cm->cm_fib->Header.SenderData = cm->cm_index;
if (cm->cm_flags & AAC_CMD_DATAIN)
bus_dmamap_sync(sc->aac_buffer_dmat, cm->cm_datamap,
BUS_DMASYNC_PREREAD);
if (cm->cm_flags & AAC_CMD_DATAOUT)
bus_dmamap_sync(sc->aac_buffer_dmat, cm->cm_datamap,
BUS_DMASYNC_PREWRITE);
cm->cm_flags |= AAC_CMD_MAPPED;
if (sc->flags & AAC_FLAGS_NEW_COMM) {
int count = 10000000L;
while (AAC_SEND_COMMAND(sc, cm) != 0) {
if (--count == 0) {
aac_unmap_command(cm);
sc->flags |= AAC_QUEUE_FRZN;
aac_requeue_ready(cm);
}
DELAY(5); /* wait 5 usec. */
}
} else {
/* Put the FIB on the outbound queue */
if (aac_enqueue_fib(sc, cm->cm_queue, cm) == EBUSY) {
aac_unmap_command(cm);
sc->flags |= AAC_QUEUE_FRZN;
aac_requeue_ready(cm);
}
}
}
/*
* Unmap a command from controller-visible space.
*/
static void
aac_unmap_command(struct aac_command *cm)
{
struct aac_softc *sc;
sc = cm->cm_sc;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
if (!(cm->cm_flags & AAC_CMD_MAPPED))
return;
if (cm->cm_datalen != 0) {
if (cm->cm_flags & AAC_CMD_DATAIN)
bus_dmamap_sync(sc->aac_buffer_dmat, cm->cm_datamap,
BUS_DMASYNC_POSTREAD);
if (cm->cm_flags & AAC_CMD_DATAOUT)
bus_dmamap_sync(sc->aac_buffer_dmat, cm->cm_datamap,
BUS_DMASYNC_POSTWRITE);
bus_dmamap_unload(sc->aac_buffer_dmat, cm->cm_datamap);
}
cm->cm_flags &= ~AAC_CMD_MAPPED;
}
/*
* Hardware Interface
*/
/*
* Initialize the adapter.
*/
static void
aac_common_map(void *arg, bus_dma_segment_t *segs, int nseg, int error)
{
struct aac_softc *sc;
sc = (struct aac_softc *)arg;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
sc->aac_common_busaddr = segs[0].ds_addr;
}
static int
aac_check_firmware(struct aac_softc *sc)
{
u_int32_t code, major, minor, options = 0, atu_size = 0;
int rid, status;
time_t then;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
/*
* Wait for the adapter to come ready.
*/
then = time_uptime;
do {
code = AAC_GET_FWSTATUS(sc);
if (code & AAC_SELF_TEST_FAILED) {
device_printf(sc->aac_dev, "FATAL: selftest failed\n");
return(ENXIO);
}
if (code & AAC_KERNEL_PANIC) {
device_printf(sc->aac_dev,
"FATAL: controller kernel panic");
return(ENXIO);
}
if (time_uptime > (then + AAC_BOOT_TIMEOUT)) {
device_printf(sc->aac_dev,
"FATAL: controller not coming ready, "
"status %x\n", code);
return(ENXIO);
}
} while (!(code & AAC_UP_AND_RUNNING));
/*
* Retrieve the firmware version numbers. Dell PERC2/QC cards with
* firmware version 1.x are not compatible with this driver.
*/
if (sc->flags & AAC_FLAGS_PERC2QC) {
if (aac_sync_command(sc, AAC_MONKER_GETKERNVER, 0, 0, 0, 0,
NULL)) {
device_printf(sc->aac_dev,
"Error reading firmware version\n");
return (EIO);
}
/* These numbers are stored as ASCII! */
major = (AAC_GET_MAILBOX(sc, 1) & 0xff) - 0x30;
minor = (AAC_GET_MAILBOX(sc, 2) & 0xff) - 0x30;
if (major == 1) {
device_printf(sc->aac_dev,
"Firmware version %d.%d is not supported.\n",
major, minor);
return (EINVAL);
}
}
/*
* Retrieve the capabilities/supported options word so we know what
* work-arounds to enable. Some firmware revs don't support this
* command.
*/
if (aac_sync_command(sc, AAC_MONKER_GETINFO, 0, 0, 0, 0, &status)) {
if (status != AAC_SRB_STS_INVALID_REQUEST) {
device_printf(sc->aac_dev,
"RequestAdapterInfo failed\n");
return (EIO);
}
} else {
options = AAC_GET_MAILBOX(sc, 1);
atu_size = AAC_GET_MAILBOX(sc, 2);
sc->supported_options = options;
if ((options & AAC_SUPPORTED_4GB_WINDOW) != 0 &&
(sc->flags & AAC_FLAGS_NO4GB) == 0)
sc->flags |= AAC_FLAGS_4GB_WINDOW;
if (options & AAC_SUPPORTED_NONDASD)
sc->flags |= AAC_FLAGS_ENABLE_CAM;
if ((options & AAC_SUPPORTED_SGMAP_HOST64) != 0
&& (sizeof(bus_addr_t) > 4)) {
device_printf(sc->aac_dev,
"Enabling 64-bit address support\n");
sc->flags |= AAC_FLAGS_SG_64BIT;
}
if ((options & AAC_SUPPORTED_NEW_COMM)
&& sc->aac_if->aif_send_command)
sc->flags |= AAC_FLAGS_NEW_COMM;
if (options & AAC_SUPPORTED_64BIT_ARRAYSIZE)
sc->flags |= AAC_FLAGS_ARRAY_64BIT;
}
/* Check for broken hardware that does a lower number of commands */
sc->aac_max_fibs = (sc->flags & AAC_FLAGS_256FIBS ? 256:512);
/* Remap mem. resource, if required */
if ((sc->flags & AAC_FLAGS_NEW_COMM) &&
atu_size > rman_get_size(sc->aac_regs_res1)) {
rid = rman_get_rid(sc->aac_regs_res1);
bus_release_resource(sc->aac_dev, SYS_RES_MEMORY, rid,
sc->aac_regs_res1);
sc->aac_regs_res1 = bus_alloc_resource_anywhere(sc->aac_dev,
SYS_RES_MEMORY, &rid, atu_size, RF_ACTIVE);
if (sc->aac_regs_res1 == NULL) {
sc->aac_regs_res1 = bus_alloc_resource_any(
sc->aac_dev, SYS_RES_MEMORY, &rid, RF_ACTIVE);
if (sc->aac_regs_res1 == NULL) {
device_printf(sc->aac_dev,
"couldn't allocate register window\n");
return (ENXIO);
}
sc->flags &= ~AAC_FLAGS_NEW_COMM;
}
sc->aac_btag1 = rman_get_bustag(sc->aac_regs_res1);
sc->aac_bhandle1 = rman_get_bushandle(sc->aac_regs_res1);
if (sc->aac_hwif == AAC_HWIF_NARK) {
sc->aac_regs_res0 = sc->aac_regs_res1;
sc->aac_btag0 = sc->aac_btag1;
sc->aac_bhandle0 = sc->aac_bhandle1;
}
}
/* Read preferred settings */
sc->aac_max_fib_size = sizeof(struct aac_fib);
sc->aac_max_sectors = 128; /* 64KB */
if (sc->flags & AAC_FLAGS_SG_64BIT)
sc->aac_sg_tablesize = (AAC_FIB_DATASIZE
- sizeof(struct aac_blockwrite64))
/ sizeof(struct aac_sg_entry64);
else
sc->aac_sg_tablesize = (AAC_FIB_DATASIZE
- sizeof(struct aac_blockwrite))
/ sizeof(struct aac_sg_entry);
if (!aac_sync_command(sc, AAC_MONKER_GETCOMMPREF, 0, 0, 0, 0, NULL)) {
options = AAC_GET_MAILBOX(sc, 1);
sc->aac_max_fib_size = (options & 0xFFFF);
sc->aac_max_sectors = (options >> 16) << 1;
options = AAC_GET_MAILBOX(sc, 2);
sc->aac_sg_tablesize = (options >> 16);
options = AAC_GET_MAILBOX(sc, 3);
sc->aac_max_fibs = (options & 0xFFFF);
}
if (sc->aac_max_fib_size > PAGE_SIZE)
sc->aac_max_fib_size = PAGE_SIZE;
sc->aac_max_fibs_alloc = PAGE_SIZE / sc->aac_max_fib_size;
if (sc->aac_max_fib_size > sizeof(struct aac_fib)) {
sc->flags |= AAC_FLAGS_RAW_IO;
device_printf(sc->aac_dev, "Enable Raw I/O\n");
}
if ((sc->flags & AAC_FLAGS_RAW_IO) &&
(sc->flags & AAC_FLAGS_ARRAY_64BIT)) {
sc->flags |= AAC_FLAGS_LBA_64BIT;
device_printf(sc->aac_dev, "Enable 64-bit array\n");
}
return (0);
}
static int
aac_init(struct aac_softc *sc)
{
struct aac_adapter_init *ip;
u_int32_t qoffset;
int error;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
/*
* Fill in the init structure. This tells the adapter about the
* physical location of various important shared data structures.
*/
ip = &sc->aac_common->ac_init;
ip->InitStructRevision = AAC_INIT_STRUCT_REVISION;
if (sc->aac_max_fib_size > sizeof(struct aac_fib)) {
ip->InitStructRevision = AAC_INIT_STRUCT_REVISION_4;
sc->flags |= AAC_FLAGS_RAW_IO;
}
ip->MiniPortRevision = AAC_INIT_STRUCT_MINIPORT_REVISION;
ip->AdapterFibsPhysicalAddress = sc->aac_common_busaddr +
offsetof(struct aac_common, ac_fibs);
ip->AdapterFibsVirtualAddress = 0;
ip->AdapterFibsSize = AAC_ADAPTER_FIBS * sizeof(struct aac_fib);
ip->AdapterFibAlign = sizeof(struct aac_fib);
ip->PrintfBufferAddress = sc->aac_common_busaddr +
offsetof(struct aac_common, ac_printf);
ip->PrintfBufferSize = AAC_PRINTF_BUFSIZE;
/*
* The adapter assumes that pages are 4K in size, except on some
* broken firmware versions that do the page->byte conversion twice,
* therefore 'assuming' that this value is in 16MB units (2^24).
* Round up since the granularity is so high.
*/
ip->HostPhysMemPages = ctob(physmem) / AAC_PAGE_SIZE;
if (sc->flags & AAC_FLAGS_BROKEN_MEMMAP) {
ip->HostPhysMemPages =
(ip->HostPhysMemPages + AAC_PAGE_SIZE) / AAC_PAGE_SIZE;
}
ip->HostElapsedSeconds = time_uptime; /* reset later if invalid */
ip->InitFlags = 0;
if (sc->flags & AAC_FLAGS_NEW_COMM) {
ip->InitFlags |= AAC_INITFLAGS_NEW_COMM_SUPPORTED;
device_printf(sc->aac_dev, "New comm. interface enabled\n");
}
ip->MaxIoCommands = sc->aac_max_fibs;
ip->MaxIoSize = sc->aac_max_sectors << 9;
ip->MaxFibSize = sc->aac_max_fib_size;
/*
* Initialize FIB queues. Note that it appears that the layout of the
* indexes and the segmentation of the entries may be mandated by the
* adapter, which is only told about the base of the queue index fields.
*
* The initial values of the indices are assumed to inform the adapter
* of the sizes of the respective queues, and theoretically it could
* work out the entire layout of the queue structures from this. We
* take the easy route and just lay this area out like everyone else
* does.
*
* The Linux driver uses a much more complex scheme whereby several
* header records are kept for each queue. We use a couple of generic
* list manipulation functions which 'know' the size of each list by
* virtue of a table.
*/
qoffset = offsetof(struct aac_common, ac_qbuf) + AAC_QUEUE_ALIGN;
qoffset &= ~(AAC_QUEUE_ALIGN - 1);
sc->aac_queues =
(struct aac_queue_table *)((uintptr_t)sc->aac_common + qoffset);
ip->CommHeaderAddress = sc->aac_common_busaddr + qoffset;
sc->aac_queues->qt_qindex[AAC_HOST_NORM_CMD_QUEUE][AAC_PRODUCER_INDEX] =
AAC_HOST_NORM_CMD_ENTRIES;
sc->aac_queues->qt_qindex[AAC_HOST_NORM_CMD_QUEUE][AAC_CONSUMER_INDEX] =
AAC_HOST_NORM_CMD_ENTRIES;
sc->aac_queues->qt_qindex[AAC_HOST_HIGH_CMD_QUEUE][AAC_PRODUCER_INDEX] =
AAC_HOST_HIGH_CMD_ENTRIES;
sc->aac_queues->qt_qindex[AAC_HOST_HIGH_CMD_QUEUE][AAC_CONSUMER_INDEX] =
AAC_HOST_HIGH_CMD_ENTRIES;
sc->aac_queues->qt_qindex[AAC_ADAP_NORM_CMD_QUEUE][AAC_PRODUCER_INDEX] =
AAC_ADAP_NORM_CMD_ENTRIES;
sc->aac_queues->qt_qindex[AAC_ADAP_NORM_CMD_QUEUE][AAC_CONSUMER_INDEX] =
AAC_ADAP_NORM_CMD_ENTRIES;
sc->aac_queues->qt_qindex[AAC_ADAP_HIGH_CMD_QUEUE][AAC_PRODUCER_INDEX] =
AAC_ADAP_HIGH_CMD_ENTRIES;
sc->aac_queues->qt_qindex[AAC_ADAP_HIGH_CMD_QUEUE][AAC_CONSUMER_INDEX] =
AAC_ADAP_HIGH_CMD_ENTRIES;
sc->aac_queues->qt_qindex[AAC_HOST_NORM_RESP_QUEUE][AAC_PRODUCER_INDEX]=
AAC_HOST_NORM_RESP_ENTRIES;
sc->aac_queues->qt_qindex[AAC_HOST_NORM_RESP_QUEUE][AAC_CONSUMER_INDEX]=
AAC_HOST_NORM_RESP_ENTRIES;
sc->aac_queues->qt_qindex[AAC_HOST_HIGH_RESP_QUEUE][AAC_PRODUCER_INDEX]=
AAC_HOST_HIGH_RESP_ENTRIES;
sc->aac_queues->qt_qindex[AAC_HOST_HIGH_RESP_QUEUE][AAC_CONSUMER_INDEX]=
AAC_HOST_HIGH_RESP_ENTRIES;
sc->aac_queues->qt_qindex[AAC_ADAP_NORM_RESP_QUEUE][AAC_PRODUCER_INDEX]=
AAC_ADAP_NORM_RESP_ENTRIES;
sc->aac_queues->qt_qindex[AAC_ADAP_NORM_RESP_QUEUE][AAC_CONSUMER_INDEX]=
AAC_ADAP_NORM_RESP_ENTRIES;
sc->aac_queues->qt_qindex[AAC_ADAP_HIGH_RESP_QUEUE][AAC_PRODUCER_INDEX]=
AAC_ADAP_HIGH_RESP_ENTRIES;
sc->aac_queues->qt_qindex[AAC_ADAP_HIGH_RESP_QUEUE][AAC_CONSUMER_INDEX]=
AAC_ADAP_HIGH_RESP_ENTRIES;
sc->aac_qentries[AAC_HOST_NORM_CMD_QUEUE] =
&sc->aac_queues->qt_HostNormCmdQueue[0];
sc->aac_qentries[AAC_HOST_HIGH_CMD_QUEUE] =
&sc->aac_queues->qt_HostHighCmdQueue[0];
sc->aac_qentries[AAC_ADAP_NORM_CMD_QUEUE] =
&sc->aac_queues->qt_AdapNormCmdQueue[0];
sc->aac_qentries[AAC_ADAP_HIGH_CMD_QUEUE] =
&sc->aac_queues->qt_AdapHighCmdQueue[0];
sc->aac_qentries[AAC_HOST_NORM_RESP_QUEUE] =
&sc->aac_queues->qt_HostNormRespQueue[0];
sc->aac_qentries[AAC_HOST_HIGH_RESP_QUEUE] =
&sc->aac_queues->qt_HostHighRespQueue[0];
sc->aac_qentries[AAC_ADAP_NORM_RESP_QUEUE] =
&sc->aac_queues->qt_AdapNormRespQueue[0];
sc->aac_qentries[AAC_ADAP_HIGH_RESP_QUEUE] =
&sc->aac_queues->qt_AdapHighRespQueue[0];
/*
* Do controller-type-specific initialisation
*/
switch (sc->aac_hwif) {
case AAC_HWIF_I960RX:
AAC_MEM0_SETREG4(sc, AAC_RX_ODBR, ~0);
break;
case AAC_HWIF_RKT:
AAC_MEM0_SETREG4(sc, AAC_RKT_ODBR, ~0);
break;
default:
break;
}
/*
* Give the init structure to the controller.
*/
if (aac_sync_command(sc, AAC_MONKER_INITSTRUCT,
sc->aac_common_busaddr +
offsetof(struct aac_common, ac_init), 0, 0, 0,
NULL)) {
device_printf(sc->aac_dev,
"error establishing init structure\n");
error = EIO;
goto out;
}
error = 0;
out:
return(error);
}
static int
aac_setup_intr(struct aac_softc *sc)
{
if (sc->flags & AAC_FLAGS_NEW_COMM) {
if (bus_setup_intr(sc->aac_dev, sc->aac_irq,
INTR_MPSAFE|INTR_TYPE_BIO, NULL,
aac_new_intr, sc, &sc->aac_intr)) {
device_printf(sc->aac_dev, "can't set up interrupt\n");
return (EINVAL);
}
} else {
if (bus_setup_intr(sc->aac_dev, sc->aac_irq,
INTR_TYPE_BIO, aac_filter, NULL,
sc, &sc->aac_intr)) {
device_printf(sc->aac_dev,
"can't set up interrupt filter\n");
return (EINVAL);
}
}
return (0);
}
/*
* Send a synchronous command to the controller and wait for a result.
* Indicate if the controller completed the command with an error status.
*/
static int
aac_sync_command(struct aac_softc *sc, u_int32_t command,
u_int32_t arg0, u_int32_t arg1, u_int32_t arg2, u_int32_t arg3,
u_int32_t *sp)
{
time_t then;
u_int32_t status;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
/* populate the mailbox */
AAC_SET_MAILBOX(sc, command, arg0, arg1, arg2, arg3);
/* ensure the sync command doorbell flag is cleared */
AAC_CLEAR_ISTATUS(sc, AAC_DB_SYNC_COMMAND);
/* then set it to signal the adapter */
AAC_QNOTIFY(sc, AAC_DB_SYNC_COMMAND);
/* spin waiting for the command to complete */
then = time_uptime;
do {
if (time_uptime > (then + AAC_IMMEDIATE_TIMEOUT)) {
fwprintf(sc, HBA_FLAGS_DBG_ERROR_B, "timed out");
return(EIO);
}
} while (!(AAC_GET_ISTATUS(sc) & AAC_DB_SYNC_COMMAND));
/* clear the completion flag */
AAC_CLEAR_ISTATUS(sc, AAC_DB_SYNC_COMMAND);
/* get the command status */
status = AAC_GET_MAILBOX(sc, 0);
if (sp != NULL)
*sp = status;
if (status != AAC_SRB_STS_SUCCESS)
return (-1);
return(0);
}
int
aac_sync_fib(struct aac_softc *sc, u_int32_t command, u_int32_t xferstate,
struct aac_fib *fib, u_int16_t datasize)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
mtx_assert(&sc->aac_io_lock, MA_OWNED);
if (datasize > AAC_FIB_DATASIZE)
return(EINVAL);
/*
* Set up the sync FIB
*/
fib->Header.XferState = AAC_FIBSTATE_HOSTOWNED |
AAC_FIBSTATE_INITIALISED |
AAC_FIBSTATE_EMPTY;
fib->Header.XferState |= xferstate;
fib->Header.Command = command;
fib->Header.StructType = AAC_FIBTYPE_TFIB;
fib->Header.Size = sizeof(struct aac_fib_header) + datasize;
fib->Header.SenderSize = sizeof(struct aac_fib);
fib->Header.SenderFibAddress = 0; /* Not needed */
fib->Header.ReceiverFibAddress = sc->aac_common_busaddr +
offsetof(struct aac_common,
ac_sync_fib);
/*
* Give the FIB to the controller, wait for a response.
*/
if (aac_sync_command(sc, AAC_MONKER_SYNCFIB,
fib->Header.ReceiverFibAddress, 0, 0, 0, NULL)) {
fwprintf(sc, HBA_FLAGS_DBG_ERROR_B, "IO error");
return(EIO);
}
return (0);
}
/*
* Adapter-space FIB queue manipulation
*
* Note that the queue implementation here is a little funky; neither the PI or
* CI will ever be zero. This behaviour is a controller feature.
*/
static const struct {
int size;
int notify;
} aac_qinfo[] = {
{AAC_HOST_NORM_CMD_ENTRIES, AAC_DB_COMMAND_NOT_FULL},
{AAC_HOST_HIGH_CMD_ENTRIES, 0},
{AAC_ADAP_NORM_CMD_ENTRIES, AAC_DB_COMMAND_READY},
{AAC_ADAP_HIGH_CMD_ENTRIES, 0},
{AAC_HOST_NORM_RESP_ENTRIES, AAC_DB_RESPONSE_NOT_FULL},
{AAC_HOST_HIGH_RESP_ENTRIES, 0},
{AAC_ADAP_NORM_RESP_ENTRIES, AAC_DB_RESPONSE_READY},
{AAC_ADAP_HIGH_RESP_ENTRIES, 0}
};
/*
* Atomically insert an entry into the nominated queue, returns 0 on success or
* EBUSY if the queue is full.
*
* Note: it would be more efficient to defer notifying the controller in
* the case where we may be inserting several entries in rapid succession,
* but implementing this usefully may be difficult (it would involve a
* separate queue/notify interface).
*/
static int
aac_enqueue_fib(struct aac_softc *sc, int queue, struct aac_command *cm)
{
u_int32_t pi, ci;
int error;
u_int32_t fib_size;
u_int32_t fib_addr;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
fib_size = cm->cm_fib->Header.Size;
fib_addr = cm->cm_fib->Header.ReceiverFibAddress;
/* get the producer/consumer indices */
pi = sc->aac_queues->qt_qindex[queue][AAC_PRODUCER_INDEX];
ci = sc->aac_queues->qt_qindex[queue][AAC_CONSUMER_INDEX];
/* wrap the queue? */
if (pi >= aac_qinfo[queue].size)
pi = 0;
/* check for queue full */
if ((pi + 1) == ci) {
error = EBUSY;
goto out;
}
/*
* To avoid a race with its completion interrupt, place this command on
* the busy queue prior to advertising it to the controller.
*/
aac_enqueue_busy(cm);
/* populate queue entry */
(sc->aac_qentries[queue] + pi)->aq_fib_size = fib_size;
(sc->aac_qentries[queue] + pi)->aq_fib_addr = fib_addr;
/* update producer index */
sc->aac_queues->qt_qindex[queue][AAC_PRODUCER_INDEX] = pi + 1;
/* notify the adapter if we know how */
if (aac_qinfo[queue].notify != 0)
AAC_QNOTIFY(sc, aac_qinfo[queue].notify);
error = 0;
out:
return(error);
}
/*
* Atomically remove one entry from the nominated queue, returns 0 on
* success or ENOENT if the queue is empty.
*/
static int
aac_dequeue_fib(struct aac_softc *sc, int queue, u_int32_t *fib_size,
struct aac_fib **fib_addr)
{
u_int32_t pi, ci;
u_int32_t fib_index;
int error;
int notify;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
/* get the producer/consumer indices */
pi = sc->aac_queues->qt_qindex[queue][AAC_PRODUCER_INDEX];
ci = sc->aac_queues->qt_qindex[queue][AAC_CONSUMER_INDEX];
/* check for queue empty */
if (ci == pi) {
error = ENOENT;
goto out;
}
/* wrap the pi so the following test works */
if (pi >= aac_qinfo[queue].size)
pi = 0;
notify = 0;
if (ci == pi + 1)
notify++;
/* wrap the queue? */
if (ci >= aac_qinfo[queue].size)
ci = 0;
/* fetch the entry */
*fib_size = (sc->aac_qentries[queue] + ci)->aq_fib_size;
switch (queue) {
case AAC_HOST_NORM_CMD_QUEUE:
case AAC_HOST_HIGH_CMD_QUEUE:
/*
* The aq_fib_addr is only 32 bits wide so it can't be counted
* on to hold an address. For AIF's, the adapter assumes
* that it's giving us an address into the array of AIF fibs.
* Therefore, we have to convert it to an index.
*/
fib_index = (sc->aac_qentries[queue] + ci)->aq_fib_addr /
sizeof(struct aac_fib);
*fib_addr = &sc->aac_common->ac_fibs[fib_index];
break;
case AAC_HOST_NORM_RESP_QUEUE:
case AAC_HOST_HIGH_RESP_QUEUE:
{
struct aac_command *cm;
/*
* As above, an index is used instead of an actual address.
* Gotta shift the index to account for the fast response
* bit. No other correction is needed since this value was
* originally provided by the driver via the SenderFibAddress
* field.
*/
fib_index = (sc->aac_qentries[queue] + ci)->aq_fib_addr;
cm = sc->aac_commands + (fib_index >> 2);
*fib_addr = cm->cm_fib;
/*
* Is this a fast response? If it is, update the fib fields in
* local memory since the whole fib isn't DMA'd back up.
*/
if (fib_index & 0x01) {
(*fib_addr)->Header.XferState |= AAC_FIBSTATE_DONEADAP;
*((u_int32_t*)((*fib_addr)->data)) = AAC_ERROR_NORMAL;
}
break;
}
default:
panic("Invalid queue in aac_dequeue_fib()");
break;
}
/* update consumer index */
sc->aac_queues->qt_qindex[queue][AAC_CONSUMER_INDEX] = ci + 1;
/* if we have made the queue un-full, notify the adapter */
if (notify && (aac_qinfo[queue].notify != 0))
AAC_QNOTIFY(sc, aac_qinfo[queue].notify);
error = 0;
out:
return(error);
}
/*
* Put our response to an Adapter Initialed Fib on the response queue
*/
static int
aac_enqueue_response(struct aac_softc *sc, int queue, struct aac_fib *fib)
{
u_int32_t pi, ci;
int error;
u_int32_t fib_size;
u_int32_t fib_addr;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
/* Tell the adapter where the FIB is */
fib_size = fib->Header.Size;
fib_addr = fib->Header.SenderFibAddress;
fib->Header.ReceiverFibAddress = fib_addr;
/* get the producer/consumer indices */
pi = sc->aac_queues->qt_qindex[queue][AAC_PRODUCER_INDEX];
ci = sc->aac_queues->qt_qindex[queue][AAC_CONSUMER_INDEX];
/* wrap the queue? */
if (pi >= aac_qinfo[queue].size)
pi = 0;
/* check for queue full */
if ((pi + 1) == ci) {
error = EBUSY;
goto out;
}
/* populate queue entry */
(sc->aac_qentries[queue] + pi)->aq_fib_size = fib_size;
(sc->aac_qentries[queue] + pi)->aq_fib_addr = fib_addr;
/* update producer index */
sc->aac_queues->qt_qindex[queue][AAC_PRODUCER_INDEX] = pi + 1;
/* notify the adapter if we know how */
if (aac_qinfo[queue].notify != 0)
AAC_QNOTIFY(sc, aac_qinfo[queue].notify);
error = 0;
out:
return(error);
}
/*
* Check for commands that have been outstanding for a suspiciously long time,
* and complain about them.
*/
static void
aac_timeout(struct aac_softc *sc)
{
struct aac_command *cm;
time_t deadline;
int timedout, code;
/*
* Traverse the busy command list, bitch about late commands once
* only.
*/
timedout = 0;
deadline = time_uptime - AAC_CMD_TIMEOUT;
TAILQ_FOREACH(cm, &sc->aac_busy, cm_link) {
if ((cm->cm_timestamp < deadline)
&& !(cm->cm_flags & AAC_CMD_TIMEDOUT)) {
cm->cm_flags |= AAC_CMD_TIMEDOUT;
device_printf(sc->aac_dev,
"COMMAND %p (TYPE %d) TIMEOUT AFTER %d SECONDS\n",
cm, cm->cm_fib->Header.Command,
(int)(time_uptime-cm->cm_timestamp));
AAC_PRINT_FIB(sc, cm->cm_fib);
timedout++;
}
}
if (timedout) {
code = AAC_GET_FWSTATUS(sc);
if (code != AAC_UP_AND_RUNNING) {
device_printf(sc->aac_dev, "WARNING! Controller is no "
"longer running! code= 0x%x\n", code);
}
}
}
/*
* Interface Function Vectors
*/
/*
* Read the current firmware status word.
*/
static int
aac_sa_get_fwstatus(struct aac_softc *sc)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
return(AAC_MEM0_GETREG4(sc, AAC_SA_FWSTATUS));
}
static int
aac_rx_get_fwstatus(struct aac_softc *sc)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
return(AAC_MEM0_GETREG4(sc, sc->flags & AAC_FLAGS_NEW_COMM ?
AAC_RX_OMR0 : AAC_RX_FWSTATUS));
}
static int
aac_rkt_get_fwstatus(struct aac_softc *sc)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
return(AAC_MEM0_GETREG4(sc, sc->flags & AAC_FLAGS_NEW_COMM ?
AAC_RKT_OMR0 : AAC_RKT_FWSTATUS));
}
/*
* Notify the controller of a change in a given queue
*/
static void
aac_sa_qnotify(struct aac_softc *sc, int qbit)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
AAC_MEM0_SETREG2(sc, AAC_SA_DOORBELL1_SET, qbit);
}
static void
aac_rx_qnotify(struct aac_softc *sc, int qbit)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
AAC_MEM0_SETREG4(sc, AAC_RX_IDBR, qbit);
}
static void
aac_rkt_qnotify(struct aac_softc *sc, int qbit)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
AAC_MEM0_SETREG4(sc, AAC_RKT_IDBR, qbit);
}
/*
* Get the interrupt reason bits
*/
static int
aac_sa_get_istatus(struct aac_softc *sc)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
return(AAC_MEM0_GETREG2(sc, AAC_SA_DOORBELL0));
}
static int
aac_rx_get_istatus(struct aac_softc *sc)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
return(AAC_MEM0_GETREG4(sc, AAC_RX_ODBR));
}
static int
aac_rkt_get_istatus(struct aac_softc *sc)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
return(AAC_MEM0_GETREG4(sc, AAC_RKT_ODBR));
}
/*
* Clear some interrupt reason bits
*/
static void
aac_sa_clear_istatus(struct aac_softc *sc, int mask)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
AAC_MEM0_SETREG2(sc, AAC_SA_DOORBELL0_CLEAR, mask);
}
static void
aac_rx_clear_istatus(struct aac_softc *sc, int mask)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
AAC_MEM0_SETREG4(sc, AAC_RX_ODBR, mask);
}
static void
aac_rkt_clear_istatus(struct aac_softc *sc, int mask)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
AAC_MEM0_SETREG4(sc, AAC_RKT_ODBR, mask);
}
/*
* Populate the mailbox and set the command word
*/
static void
aac_sa_set_mailbox(struct aac_softc *sc, u_int32_t command,
u_int32_t arg0, u_int32_t arg1, u_int32_t arg2, u_int32_t arg3)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
AAC_MEM1_SETREG4(sc, AAC_SA_MAILBOX, command);
AAC_MEM1_SETREG4(sc, AAC_SA_MAILBOX + 4, arg0);
AAC_MEM1_SETREG4(sc, AAC_SA_MAILBOX + 8, arg1);
AAC_MEM1_SETREG4(sc, AAC_SA_MAILBOX + 12, arg2);
AAC_MEM1_SETREG4(sc, AAC_SA_MAILBOX + 16, arg3);
}
static void
aac_rx_set_mailbox(struct aac_softc *sc, u_int32_t command,
u_int32_t arg0, u_int32_t arg1, u_int32_t arg2, u_int32_t arg3)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
AAC_MEM1_SETREG4(sc, AAC_RX_MAILBOX, command);
AAC_MEM1_SETREG4(sc, AAC_RX_MAILBOX + 4, arg0);
AAC_MEM1_SETREG4(sc, AAC_RX_MAILBOX + 8, arg1);
AAC_MEM1_SETREG4(sc, AAC_RX_MAILBOX + 12, arg2);
AAC_MEM1_SETREG4(sc, AAC_RX_MAILBOX + 16, arg3);
}
static void
aac_rkt_set_mailbox(struct aac_softc *sc, u_int32_t command, u_int32_t arg0,
u_int32_t arg1, u_int32_t arg2, u_int32_t arg3)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
AAC_MEM1_SETREG4(sc, AAC_RKT_MAILBOX, command);
AAC_MEM1_SETREG4(sc, AAC_RKT_MAILBOX + 4, arg0);
AAC_MEM1_SETREG4(sc, AAC_RKT_MAILBOX + 8, arg1);
AAC_MEM1_SETREG4(sc, AAC_RKT_MAILBOX + 12, arg2);
AAC_MEM1_SETREG4(sc, AAC_RKT_MAILBOX + 16, arg3);
}
/*
* Fetch the immediate command status word
*/
static int
aac_sa_get_mailbox(struct aac_softc *sc, int mb)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
return(AAC_MEM1_GETREG4(sc, AAC_SA_MAILBOX + (mb * 4)));
}
static int
aac_rx_get_mailbox(struct aac_softc *sc, int mb)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
return(AAC_MEM1_GETREG4(sc, AAC_RX_MAILBOX + (mb * 4)));
}
static int
aac_rkt_get_mailbox(struct aac_softc *sc, int mb)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
return(AAC_MEM1_GETREG4(sc, AAC_RKT_MAILBOX + (mb * 4)));
}
/*
* Set/clear interrupt masks
*/
static void
aac_sa_set_interrupts(struct aac_softc *sc, int enable)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "%sable interrupts", enable ? "en" : "dis");
if (enable) {
AAC_MEM0_SETREG2((sc), AAC_SA_MASK0_CLEAR, AAC_DB_INTERRUPTS);
} else {
AAC_MEM0_SETREG2((sc), AAC_SA_MASK0_SET, ~0);
}
}
static void
aac_rx_set_interrupts(struct aac_softc *sc, int enable)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "%sable interrupts", enable ? "en" : "dis");
if (enable) {
if (sc->flags & AAC_FLAGS_NEW_COMM)
AAC_MEM0_SETREG4(sc, AAC_RX_OIMR, ~AAC_DB_INT_NEW_COMM);
else
AAC_MEM0_SETREG4(sc, AAC_RX_OIMR, ~AAC_DB_INTERRUPTS);
} else {
AAC_MEM0_SETREG4(sc, AAC_RX_OIMR, ~0);
}
}
static void
aac_rkt_set_interrupts(struct aac_softc *sc, int enable)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "%sable interrupts", enable ? "en" : "dis");
if (enable) {
if (sc->flags & AAC_FLAGS_NEW_COMM)
AAC_MEM0_SETREG4(sc, AAC_RKT_OIMR, ~AAC_DB_INT_NEW_COMM);
else
AAC_MEM0_SETREG4(sc, AAC_RKT_OIMR, ~AAC_DB_INTERRUPTS);
} else {
AAC_MEM0_SETREG4(sc, AAC_RKT_OIMR, ~0);
}
}
/*
* New comm. interface: Send command functions
*/
static int
aac_rx_send_command(struct aac_softc *sc, struct aac_command *cm)
{
u_int32_t index, device;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "send command (new comm.)");
index = AAC_MEM0_GETREG4(sc, AAC_RX_IQUE);
if (index == 0xffffffffL)
index = AAC_MEM0_GETREG4(sc, AAC_RX_IQUE);
if (index == 0xffffffffL)
return index;
aac_enqueue_busy(cm);
device = index;
AAC_MEM1_SETREG4(sc, device, (u_int32_t)(cm->cm_fibphys & 0xffffffffUL));
device += 4;
AAC_MEM1_SETREG4(sc, device, (u_int32_t)(cm->cm_fibphys >> 32));
device += 4;
AAC_MEM1_SETREG4(sc, device, cm->cm_fib->Header.Size);
AAC_MEM0_SETREG4(sc, AAC_RX_IQUE, index);
return 0;
}
static int
aac_rkt_send_command(struct aac_softc *sc, struct aac_command *cm)
{
u_int32_t index, device;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "send command (new comm.)");
index = AAC_MEM0_GETREG4(sc, AAC_RKT_IQUE);
if (index == 0xffffffffL)
index = AAC_MEM0_GETREG4(sc, AAC_RKT_IQUE);
if (index == 0xffffffffL)
return index;
aac_enqueue_busy(cm);
device = index;
AAC_MEM1_SETREG4(sc, device, (u_int32_t)(cm->cm_fibphys & 0xffffffffUL));
device += 4;
AAC_MEM1_SETREG4(sc, device, (u_int32_t)(cm->cm_fibphys >> 32));
device += 4;
AAC_MEM1_SETREG4(sc, device, cm->cm_fib->Header.Size);
AAC_MEM0_SETREG4(sc, AAC_RKT_IQUE, index);
return 0;
}
/*
* New comm. interface: get, set outbound queue index
*/
static int
aac_rx_get_outb_queue(struct aac_softc *sc)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
return(AAC_MEM0_GETREG4(sc, AAC_RX_OQUE));
}
static int
aac_rkt_get_outb_queue(struct aac_softc *sc)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
return(AAC_MEM0_GETREG4(sc, AAC_RKT_OQUE));
}
static void
aac_rx_set_outb_queue(struct aac_softc *sc, int index)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
AAC_MEM0_SETREG4(sc, AAC_RX_OQUE, index);
}
static void
aac_rkt_set_outb_queue(struct aac_softc *sc, int index)
{
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
AAC_MEM0_SETREG4(sc, AAC_RKT_OQUE, index);
}
/*
* Debugging and Diagnostics
*/
/*
* Print some information about the controller.
*/
static void
aac_describe_controller(struct aac_softc *sc)
{
struct aac_fib *fib;
struct aac_adapter_info *info;
char *adapter_type = "Adaptec RAID controller";
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
mtx_lock(&sc->aac_io_lock);
aac_alloc_sync_fib(sc, &fib);
fib->data[0] = 0;
if (aac_sync_fib(sc, RequestAdapterInfo, 0, fib, 1)) {
device_printf(sc->aac_dev, "RequestAdapterInfo failed\n");
aac_release_sync_fib(sc);
mtx_unlock(&sc->aac_io_lock);
return;
}
/* save the kernel revision structure for later use */
info = (struct aac_adapter_info *)&fib->data[0];
sc->aac_revision = info->KernelRevision;
if (bootverbose) {
device_printf(sc->aac_dev, "%s %dMHz, %dMB memory "
"(%dMB cache, %dMB execution), %s\n",
aac_describe_code(aac_cpu_variant, info->CpuVariant),
info->ClockSpeed, info->TotalMem / (1024 * 1024),
info->BufferMem / (1024 * 1024),
info->ExecutionMem / (1024 * 1024),
aac_describe_code(aac_battery_platform,
info->batteryPlatform));
device_printf(sc->aac_dev,
"Kernel %d.%d-%d, Build %d, S/N %6X\n",
info->KernelRevision.external.comp.major,
info->KernelRevision.external.comp.minor,
info->KernelRevision.external.comp.dash,
info->KernelRevision.buildNumber,
(u_int32_t)(info->SerialNumber & 0xffffff));
device_printf(sc->aac_dev, "Supported Options=%b\n",
sc->supported_options,
"\20"
"\1SNAPSHOT"
"\2CLUSTERS"
"\3WCACHE"
"\4DATA64"
"\5HOSTTIME"
"\6RAID50"
"\7WINDOW4GB"
"\10SCSIUPGD"
"\11SOFTERR"
"\12NORECOND"
"\13SGMAP64"
"\14ALARM"
"\15NONDASD"
"\16SCSIMGT"
"\17RAIDSCSI"
"\21ADPTINFO"
"\22NEWCOMM"
"\23ARRAY64BIT"
"\24HEATSENSOR");
}
if (sc->supported_options & AAC_SUPPORTED_SUPPLEMENT_ADAPTER_INFO) {
fib->data[0] = 0;
if (aac_sync_fib(sc, RequestSupplementAdapterInfo, 0, fib, 1))
device_printf(sc->aac_dev,
"RequestSupplementAdapterInfo failed\n");
else
adapter_type = ((struct aac_supplement_adapter_info *)
&fib->data[0])->AdapterTypeText;
}
device_printf(sc->aac_dev, "%s, aac driver %d.%d.%d-%d\n",
adapter_type,
AAC_DRIVER_MAJOR_VERSION, AAC_DRIVER_MINOR_VERSION,
AAC_DRIVER_BUGFIX_LEVEL, AAC_DRIVER_BUILD);
aac_release_sync_fib(sc);
mtx_unlock(&sc->aac_io_lock);
}
/*
* Look up a text description of a numeric error code and return a pointer to
* same.
*/
static const char *
aac_describe_code(const struct aac_code_lookup *table, u_int32_t code)
{
int i;
for (i = 0; table[i].string != NULL; i++)
if (table[i].code == code)
return(table[i].string);
return(table[i + 1].string);
}
/*
* Management Interface
*/
static int
aac_open(struct cdev *dev, int flags, int fmt, struct thread *td)
{
struct aac_softc *sc;
sc = dev->si_drv1;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
device_busy(sc->aac_dev);
devfs_set_cdevpriv(sc, aac_cdevpriv_dtor);
return 0;
}
static int
aac_ioctl(struct cdev *dev, u_long cmd, caddr_t arg, int flag, struct thread *td)
{
union aac_statrequest *as;
struct aac_softc *sc;
int error = 0;
as = (union aac_statrequest *)arg;
sc = dev->si_drv1;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
switch (cmd) {
case AACIO_STATS:
switch (as->as_item) {
case AACQ_FREE:
case AACQ_BIO:
case AACQ_READY:
case AACQ_BUSY:
bcopy(&sc->aac_qstat[as->as_item], &as->as_qstat,
sizeof(struct aac_qstat));
break;
default:
error = ENOENT;
break;
}
break;
case FSACTL_SENDFIB:
case FSACTL_SEND_LARGE_FIB:
arg = *(caddr_t*)arg;
case FSACTL_LNX_SENDFIB:
case FSACTL_LNX_SEND_LARGE_FIB:
fwprintf(sc, HBA_FLAGS_DBG_IOCTL_COMMANDS_B, "FSACTL_SENDFIB");
error = aac_ioctl_sendfib(sc, arg);
break;
case FSACTL_SEND_RAW_SRB:
arg = *(caddr_t*)arg;
case FSACTL_LNX_SEND_RAW_SRB:
fwprintf(sc, HBA_FLAGS_DBG_IOCTL_COMMANDS_B, "FSACTL_SEND_RAW_SRB");
error = aac_ioctl_send_raw_srb(sc, arg);
break;
case FSACTL_AIF_THREAD:
case FSACTL_LNX_AIF_THREAD:
fwprintf(sc, HBA_FLAGS_DBG_IOCTL_COMMANDS_B, "FSACTL_AIF_THREAD");
error = EINVAL;
break;
case FSACTL_OPEN_GET_ADAPTER_FIB:
arg = *(caddr_t*)arg;
case FSACTL_LNX_OPEN_GET_ADAPTER_FIB:
fwprintf(sc, HBA_FLAGS_DBG_IOCTL_COMMANDS_B, "FSACTL_OPEN_GET_ADAPTER_FIB");
error = aac_open_aif(sc, arg);
break;
case FSACTL_GET_NEXT_ADAPTER_FIB:
arg = *(caddr_t*)arg;
case FSACTL_LNX_GET_NEXT_ADAPTER_FIB:
fwprintf(sc, HBA_FLAGS_DBG_IOCTL_COMMANDS_B, "FSACTL_GET_NEXT_ADAPTER_FIB");
error = aac_getnext_aif(sc, arg);
break;
case FSACTL_CLOSE_GET_ADAPTER_FIB:
arg = *(caddr_t*)arg;
case FSACTL_LNX_CLOSE_GET_ADAPTER_FIB:
fwprintf(sc, HBA_FLAGS_DBG_IOCTL_COMMANDS_B, "FSACTL_CLOSE_GET_ADAPTER_FIB");
error = aac_close_aif(sc, arg);
break;
case FSACTL_MINIPORT_REV_CHECK:
arg = *(caddr_t*)arg;
case FSACTL_LNX_MINIPORT_REV_CHECK:
fwprintf(sc, HBA_FLAGS_DBG_IOCTL_COMMANDS_B, "FSACTL_MINIPORT_REV_CHECK");
error = aac_rev_check(sc, arg);
break;
case FSACTL_QUERY_DISK:
arg = *(caddr_t*)arg;
case FSACTL_LNX_QUERY_DISK:
fwprintf(sc, HBA_FLAGS_DBG_IOCTL_COMMANDS_B, "FSACTL_QUERY_DISK");
error = aac_query_disk(sc, arg);
break;
case FSACTL_DELETE_DISK:
case FSACTL_LNX_DELETE_DISK:
/*
* We don't trust the underland to tell us when to delete a
* container, rather we rely on an AIF coming from the
* controller
*/
error = 0;
break;
case FSACTL_GET_PCI_INFO:
arg = *(caddr_t*)arg;
case FSACTL_LNX_GET_PCI_INFO:
fwprintf(sc, HBA_FLAGS_DBG_IOCTL_COMMANDS_B, "FSACTL_GET_PCI_INFO");
error = aac_get_pci_info(sc, arg);
break;
case FSACTL_GET_FEATURES:
arg = *(caddr_t*)arg;
case FSACTL_LNX_GET_FEATURES:
fwprintf(sc, HBA_FLAGS_DBG_IOCTL_COMMANDS_B, "FSACTL_GET_FEATURES");
error = aac_supported_features(sc, arg);
break;
default:
fwprintf(sc, HBA_FLAGS_DBG_IOCTL_COMMANDS_B, "unsupported cmd 0x%lx\n", cmd);
error = EINVAL;
break;
}
return(error);
}
static int
aac_poll(struct cdev *dev, int poll_events, struct thread *td)
{
struct aac_softc *sc;
struct aac_fib_context *ctx;
int revents;
sc = dev->si_drv1;
revents = 0;
mtx_lock(&sc->aac_aifq_lock);
if ((poll_events & (POLLRDNORM | POLLIN)) != 0) {
for (ctx = sc->fibctx; ctx; ctx = ctx->next) {
if (ctx->ctx_idx != sc->aifq_idx || ctx->ctx_wrap) {
revents |= poll_events & (POLLIN | POLLRDNORM);
break;
}
}
}
mtx_unlock(&sc->aac_aifq_lock);
if (revents == 0) {
if (poll_events & (POLLIN | POLLRDNORM))
selrecord(td, &sc->rcv_select);
}
return (revents);
}
static void
aac_ioctl_event(struct aac_softc *sc, struct aac_event *event, void *arg)
{
switch (event->ev_type) {
case AAC_EVENT_CMFREE:
mtx_assert(&sc->aac_io_lock, MA_OWNED);
if (aac_alloc_command(sc, (struct aac_command **)arg)) {
aac_add_event(sc, event);
return;
}
free(event, M_AACBUF);
wakeup(arg);
break;
default:
break;
}
}
/*
* Send a FIB supplied from userspace
*/
static int
aac_ioctl_sendfib(struct aac_softc *sc, caddr_t ufib)
{
struct aac_command *cm;
int size, error;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
cm = NULL;
/*
* Get a command
*/
mtx_lock(&sc->aac_io_lock);
if (aac_alloc_command(sc, &cm)) {
struct aac_event *event;
event = malloc(sizeof(struct aac_event), M_AACBUF,
M_NOWAIT | M_ZERO);
if (event == NULL) {
error = EBUSY;
mtx_unlock(&sc->aac_io_lock);
goto out;
}
event->ev_type = AAC_EVENT_CMFREE;
event->ev_callback = aac_ioctl_event;
event->ev_arg = &cm;
aac_add_event(sc, event);
msleep(&cm, &sc->aac_io_lock, 0, "sendfib", 0);
}
mtx_unlock(&sc->aac_io_lock);
/*
* Fetch the FIB header, then re-copy to get data as well.
*/
if ((error = copyin(ufib, cm->cm_fib,
sizeof(struct aac_fib_header))) != 0)
goto out;
size = cm->cm_fib->Header.Size + sizeof(struct aac_fib_header);
if (size > sc->aac_max_fib_size) {
device_printf(sc->aac_dev, "incoming FIB oversized (%d > %d)\n",
size, sc->aac_max_fib_size);
size = sc->aac_max_fib_size;
}
if ((error = copyin(ufib, cm->cm_fib, size)) != 0)
goto out;
cm->cm_fib->Header.Size = size;
cm->cm_timestamp = time_uptime;
/*
* Pass the FIB to the controller, wait for it to complete.
*/
mtx_lock(&sc->aac_io_lock);
error = aac_wait_command(cm);
mtx_unlock(&sc->aac_io_lock);
if (error != 0) {
device_printf(sc->aac_dev,
"aac_wait_command return %d\n", error);
goto out;
}
/*
* Copy the FIB and data back out to the caller.
*/
size = cm->cm_fib->Header.Size;
if (size > sc->aac_max_fib_size) {
device_printf(sc->aac_dev, "outbound FIB oversized (%d > %d)\n",
size, sc->aac_max_fib_size);
size = sc->aac_max_fib_size;
}
error = copyout(cm->cm_fib, ufib, size);
out:
if (cm != NULL) {
mtx_lock(&sc->aac_io_lock);
aac_release_command(cm);
mtx_unlock(&sc->aac_io_lock);
}
return(error);
}
/*
* Send a passthrough FIB supplied from userspace
*/
static int
aac_ioctl_send_raw_srb(struct aac_softc *sc, caddr_t arg)
{
struct aac_command *cm;
struct aac_event *event;
struct aac_fib *fib;
struct aac_srb *srbcmd, *user_srb;
struct aac_sg_entry *sge;
void *srb_sg_address, *ureply;
uint32_t fibsize, srb_sg_bytecount;
int error, transfer_data;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
cm = NULL;
transfer_data = 0;
fibsize = 0;
user_srb = (struct aac_srb *)arg;
mtx_lock(&sc->aac_io_lock);
if (aac_alloc_command(sc, &cm)) {
event = malloc(sizeof(struct aac_event), M_AACBUF,
M_NOWAIT | M_ZERO);
if (event == NULL) {
error = EBUSY;
mtx_unlock(&sc->aac_io_lock);
goto out;
}
event->ev_type = AAC_EVENT_CMFREE;
event->ev_callback = aac_ioctl_event;
event->ev_arg = &cm;
aac_add_event(sc, event);
msleep(cm, &sc->aac_io_lock, 0, "aacraw", 0);
}
mtx_unlock(&sc->aac_io_lock);
cm->cm_data = NULL;
fib = cm->cm_fib;
srbcmd = (struct aac_srb *)fib->data;
error = copyin(&user_srb->data_len, &fibsize, sizeof(uint32_t));
if (error != 0)
goto out;
if (fibsize > (sc->aac_max_fib_size - sizeof(struct aac_fib_header))) {
error = EINVAL;
goto out;
}
error = copyin(user_srb, srbcmd, fibsize);
if (error != 0)
goto out;
srbcmd->function = 0;
srbcmd->retry_limit = 0;
if (srbcmd->sg_map.SgCount > 1) {
error = EINVAL;
goto out;
}
/* Retrieve correct SG entries. */
if (fibsize == (sizeof(struct aac_srb) +
srbcmd->sg_map.SgCount * sizeof(struct aac_sg_entry))) {
struct aac_sg_entry sg;
sge = srbcmd->sg_map.SgEntry;
if ((error = copyin(sge, &sg, sizeof(sg))) != 0)
goto out;
srb_sg_bytecount = sg.SgByteCount;
srb_sg_address = (void *)(uintptr_t)sg.SgAddress;
}
#ifdef __amd64__
else if (fibsize == (sizeof(struct aac_srb) +
srbcmd->sg_map.SgCount * sizeof(struct aac_sg_entry64))) {
struct aac_sg_entry64 *sge64;
struct aac_sg_entry64 sg;
sge = NULL;
sge64 = (struct aac_sg_entry64 *)srbcmd->sg_map.SgEntry;
if ((error = copyin(sge64, &sg, sizeof(sg))) != 0)
goto out;
srb_sg_bytecount = sg.SgByteCount;
srb_sg_address = (void *)sg.SgAddress;
if (sge64->SgAddress > 0xffffffffull &&
(sc->flags & AAC_FLAGS_SG_64BIT) == 0) {
error = EINVAL;
goto out;
}
}
#endif
else {
error = EINVAL;
goto out;
}
ureply = (char *)arg + fibsize;
srbcmd->data_len = srb_sg_bytecount;
if (srbcmd->sg_map.SgCount == 1)
transfer_data = 1;
cm->cm_sgtable = (struct aac_sg_table *)&srbcmd->sg_map;
if (transfer_data) {
cm->cm_datalen = srb_sg_bytecount;
cm->cm_data = malloc(cm->cm_datalen, M_AACBUF, M_NOWAIT);
if (cm->cm_data == NULL) {
error = ENOMEM;
goto out;
}
if (srbcmd->flags & AAC_SRB_FLAGS_DATA_IN)
cm->cm_flags |= AAC_CMD_DATAIN;
if (srbcmd->flags & AAC_SRB_FLAGS_DATA_OUT) {
cm->cm_flags |= AAC_CMD_DATAOUT;
error = copyin(srb_sg_address, cm->cm_data,
cm->cm_datalen);
if (error != 0)
goto out;
}
}
fib->Header.Size = sizeof(struct aac_fib_header) +
sizeof(struct aac_srb);
fib->Header.XferState =
AAC_FIBSTATE_HOSTOWNED |
AAC_FIBSTATE_INITIALISED |
AAC_FIBSTATE_EMPTY |
AAC_FIBSTATE_FROMHOST |
AAC_FIBSTATE_REXPECTED |
AAC_FIBSTATE_NORM |
AAC_FIBSTATE_ASYNC |
AAC_FIBSTATE_FAST_RESPONSE;
fib->Header.Command = (sc->flags & AAC_FLAGS_SG_64BIT) != 0 ?
ScsiPortCommandU64 : ScsiPortCommand;
mtx_lock(&sc->aac_io_lock);
aac_wait_command(cm);
mtx_unlock(&sc->aac_io_lock);
if (transfer_data && (srbcmd->flags & AAC_SRB_FLAGS_DATA_IN) != 0) {
error = copyout(cm->cm_data, srb_sg_address, cm->cm_datalen);
if (error != 0)
goto out;
}
error = copyout(fib->data, ureply, sizeof(struct aac_srb_response));
out:
if (cm != NULL) {
if (cm->cm_data != NULL)
free(cm->cm_data, M_AACBUF);
mtx_lock(&sc->aac_io_lock);
aac_release_command(cm);
mtx_unlock(&sc->aac_io_lock);
}
return(error);
}
/*
* cdevpriv interface private destructor.
*/
static void
aac_cdevpriv_dtor(void *arg)
{
struct aac_softc *sc;
sc = arg;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
device_unbusy(sc->aac_dev);
}
/*
* Handle an AIF sent to us by the controller; queue it for later reference.
* If the queue fills up, then drop the older entries.
*/
static void
aac_handle_aif(struct aac_softc *sc, struct aac_fib *fib)
{
struct aac_aif_command *aif;
struct aac_container *co, *co_next;
struct aac_fib_context *ctx;
struct aac_mntinforesp *mir;
int next, current, found;
int count = 0, added = 0, i = 0;
uint32_t channel;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
aif = (struct aac_aif_command*)&fib->data[0];
aac_print_aif(sc, aif);
/* Is it an event that we should care about? */
switch (aif->command) {
case AifCmdEventNotify:
switch (aif->data.EN.type) {
case AifEnAddContainer:
case AifEnDeleteContainer:
/*
* A container was added or deleted, but the message
* doesn't tell us anything else! Re-enumerate the
* containers and sort things out.
*/
aac_alloc_sync_fib(sc, &fib);
do {
/*
* Ask the controller for its containers one at
* a time.
* XXX What if the controller's list changes
* midway through this enumaration?
* XXX This should be done async.
*/
if ((mir = aac_get_container_info(sc, fib, i)) == NULL)
continue;
if (i == 0)
count = mir->MntRespCount;
/*
* Check the container against our list.
* co->co_found was already set to 0 in a
* previous run.
*/
if ((mir->Status == ST_OK) &&
(mir->MntTable[0].VolType != CT_NONE)) {
found = 0;
TAILQ_FOREACH(co,
&sc->aac_container_tqh,
co_link) {
if (co->co_mntobj.ObjectId ==
mir->MntTable[0].ObjectId) {
co->co_found = 1;
found = 1;
break;
}
}
/*
* If the container matched, continue
* in the list.
*/
if (found) {
i++;
continue;
}
/*
* This is a new container. Do all the
* appropriate things to set it up.
*/
aac_add_container(sc, mir, 1);
added = 1;
}
i++;
} while ((i < count) && (i < AAC_MAX_CONTAINERS));
aac_release_sync_fib(sc);
/*
* Go through our list of containers and see which ones
* were not marked 'found'. Since the controller didn't
* list them they must have been deleted. Do the
* appropriate steps to destroy the device. Also reset
* the co->co_found field.
*/
co = TAILQ_FIRST(&sc->aac_container_tqh);
while (co != NULL) {
if (co->co_found == 0) {
mtx_unlock(&sc->aac_io_lock);
bus_topo_lock();
device_delete_child(sc->aac_dev,
co->co_disk);
bus_topo_unlock();
mtx_lock(&sc->aac_io_lock);
co_next = TAILQ_NEXT(co, co_link);
mtx_lock(&sc->aac_container_lock);
TAILQ_REMOVE(&sc->aac_container_tqh, co,
co_link);
mtx_unlock(&sc->aac_container_lock);
free(co, M_AACBUF);
co = co_next;
} else {
co->co_found = 0;
co = TAILQ_NEXT(co, co_link);
}
}
/* Attach the newly created containers */
if (added) {
mtx_unlock(&sc->aac_io_lock);
bus_topo_lock();
bus_generic_attach(sc->aac_dev);
bus_topo_unlock();
mtx_lock(&sc->aac_io_lock);
}
break;
case AifEnEnclosureManagement:
switch (aif->data.EN.data.EEE.eventType) {
case AIF_EM_DRIVE_INSERTION:
case AIF_EM_DRIVE_REMOVAL:
channel = aif->data.EN.data.EEE.unitID;
if (sc->cam_rescan_cb != NULL)
sc->cam_rescan_cb(sc,
(channel >> 24) & 0xF,
(channel & 0xFFFF));
break;
}
break;
case AifEnAddJBOD:
case AifEnDeleteJBOD:
channel = aif->data.EN.data.ECE.container;
if (sc->cam_rescan_cb != NULL)
sc->cam_rescan_cb(sc, (channel >> 24) & 0xF,
AAC_CAM_TARGET_WILDCARD);
break;
default:
break;
}
default:
break;
}
/* Copy the AIF data to the AIF queue for ioctl retrieval */
mtx_lock(&sc->aac_aifq_lock);
current = sc->aifq_idx;
next = (current + 1) % AAC_AIFQ_LENGTH;
if (next == 0)
sc->aifq_filled = 1;
bcopy(fib, &sc->aac_aifq[current], sizeof(struct aac_fib));
/* modify AIF contexts */
if (sc->aifq_filled) {
for (ctx = sc->fibctx; ctx; ctx = ctx->next) {
if (next == ctx->ctx_idx)
ctx->ctx_wrap = 1;
else if (current == ctx->ctx_idx && ctx->ctx_wrap)
ctx->ctx_idx = next;
}
}
sc->aifq_idx = next;
/* On the off chance that someone is sleeping for an aif... */
if (sc->aac_state & AAC_STATE_AIF_SLEEPER)
wakeup(sc->aac_aifq);
/* Wakeup any poll()ers */
selwakeuppri(&sc->rcv_select, PRIBIO);
mtx_unlock(&sc->aac_aifq_lock);
}
/*
* Return the Revision of the driver to userspace and check to see if the
* userspace app is possibly compatible. This is extremely bogus since
* our driver doesn't follow Adaptec's versioning system. Cheat by just
* returning what the card reported.
*/
static int
aac_rev_check(struct aac_softc *sc, caddr_t udata)
{
struct aac_rev_check rev_check;
struct aac_rev_check_resp rev_check_resp;
int error = 0;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
/*
* Copyin the revision struct from userspace
*/
if ((error = copyin(udata, (caddr_t)&rev_check,
sizeof(struct aac_rev_check))) != 0) {
return error;
}
fwprintf(sc, HBA_FLAGS_DBG_IOCTL_COMMANDS_B, "Userland revision= %d\n",
rev_check.callingRevision.buildNumber);
/*
* Doctor up the response struct.
*/
rev_check_resp.possiblyCompatible = 1;
rev_check_resp.adapterSWRevision.external.comp.major =
AAC_DRIVER_MAJOR_VERSION;
rev_check_resp.adapterSWRevision.external.comp.minor =
AAC_DRIVER_MINOR_VERSION;
rev_check_resp.adapterSWRevision.external.comp.type =
AAC_DRIVER_TYPE;
rev_check_resp.adapterSWRevision.external.comp.dash =
AAC_DRIVER_BUGFIX_LEVEL;
rev_check_resp.adapterSWRevision.buildNumber =
AAC_DRIVER_BUILD;
return(copyout((caddr_t)&rev_check_resp, udata,
sizeof(struct aac_rev_check_resp)));
}
/*
* Pass the fib context to the caller
*/
static int
aac_open_aif(struct aac_softc *sc, caddr_t arg)
{
struct aac_fib_context *fibctx, *ctx;
int error = 0;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
fibctx = malloc(sizeof(struct aac_fib_context), M_AACBUF, M_NOWAIT|M_ZERO);
if (fibctx == NULL)
return (ENOMEM);
mtx_lock(&sc->aac_aifq_lock);
/* all elements are already 0, add to queue */
if (sc->fibctx == NULL)
sc->fibctx = fibctx;
else {
for (ctx = sc->fibctx; ctx->next; ctx = ctx->next)
;
ctx->next = fibctx;
fibctx->prev = ctx;
}
/* evaluate unique value */
fibctx->unique = (*(u_int32_t *)&fibctx & 0xffffffff);
ctx = sc->fibctx;
while (ctx != fibctx) {
if (ctx->unique == fibctx->unique) {
fibctx->unique++;
ctx = sc->fibctx;
} else {
ctx = ctx->next;
}
}
mtx_unlock(&sc->aac_aifq_lock);
error = copyout(&fibctx->unique, (void *)arg, sizeof(u_int32_t));
if (error)
aac_close_aif(sc, (caddr_t)ctx);
return error;
}
/*
* Close the caller's fib context
*/
static int
aac_close_aif(struct aac_softc *sc, caddr_t arg)
{
struct aac_fib_context *ctx;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
mtx_lock(&sc->aac_aifq_lock);
for (ctx = sc->fibctx; ctx; ctx = ctx->next) {
if (ctx->unique == *(uint32_t *)&arg) {
if (ctx == sc->fibctx)
sc->fibctx = NULL;
else {
ctx->prev->next = ctx->next;
if (ctx->next)
ctx->next->prev = ctx->prev;
}
break;
}
}
mtx_unlock(&sc->aac_aifq_lock);
if (ctx)
free(ctx, M_AACBUF);
return 0;
}
/*
* Pass the caller the next AIF in their queue
*/
static int
aac_getnext_aif(struct aac_softc *sc, caddr_t arg)
{
struct get_adapter_fib_ioctl agf;
struct aac_fib_context *ctx;
int error;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
#ifdef COMPAT_FREEBSD32
if (SV_CURPROC_FLAG(SV_ILP32)) {
struct get_adapter_fib_ioctl32 agf32;
error = copyin(arg, &agf32, sizeof(agf32));
if (error == 0) {
agf.AdapterFibContext = agf32.AdapterFibContext;
agf.Wait = agf32.Wait;
agf.AifFib = (caddr_t)(uintptr_t)agf32.AifFib;
}
} else
#endif
error = copyin(arg, &agf, sizeof(agf));
if (error == 0) {
for (ctx = sc->fibctx; ctx; ctx = ctx->next) {
if (agf.AdapterFibContext == ctx->unique)
break;
}
if (!ctx)
return (EFAULT);
error = aac_return_aif(sc, ctx, agf.AifFib);
if (error == EAGAIN && agf.Wait) {
fwprintf(sc, HBA_FLAGS_DBG_AIF_B, "aac_getnext_aif(): waiting for AIF");
sc->aac_state |= AAC_STATE_AIF_SLEEPER;
while (error == EAGAIN) {
error = tsleep(sc->aac_aifq, PRIBIO |
PCATCH, "aacaif", 0);
if (error == 0)
error = aac_return_aif(sc, ctx, agf.AifFib);
}
sc->aac_state &= ~AAC_STATE_AIF_SLEEPER;
}
}
return(error);
}
/*
* Hand the next AIF off the top of the queue out to userspace.
*/
static int
aac_return_aif(struct aac_softc *sc, struct aac_fib_context *ctx, caddr_t uptr)
{
int current, error;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
mtx_lock(&sc->aac_aifq_lock);
current = ctx->ctx_idx;
if (current == sc->aifq_idx && !ctx->ctx_wrap) {
/* empty */
mtx_unlock(&sc->aac_aifq_lock);
return (EAGAIN);
}
error =
copyout(&sc->aac_aifq[current], (void *)uptr, sizeof(struct aac_fib));
if (error)
device_printf(sc->aac_dev,
"aac_return_aif: copyout returned %d\n", error);
else {
ctx->ctx_wrap = 0;
ctx->ctx_idx = (current + 1) % AAC_AIFQ_LENGTH;
}
mtx_unlock(&sc->aac_aifq_lock);
return(error);
}
static int
aac_get_pci_info(struct aac_softc *sc, caddr_t uptr)
{
struct aac_pci_info {
u_int32_t bus;
u_int32_t slot;
} pciinf;
int error;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
pciinf.bus = pci_get_bus(sc->aac_dev);
pciinf.slot = pci_get_slot(sc->aac_dev);
error = copyout((caddr_t)&pciinf, uptr,
sizeof(struct aac_pci_info));
return (error);
}
static int
aac_supported_features(struct aac_softc *sc, caddr_t uptr)
{
struct aac_features f;
int error;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
if ((error = copyin(uptr, &f, sizeof (f))) != 0)
return (error);
/*
* When the management driver receives FSACTL_GET_FEATURES ioctl with
* ALL zero in the featuresState, the driver will return the current
* state of all the supported features, the data field will not be
* valid.
* When the management driver receives FSACTL_GET_FEATURES ioctl with
* a specific bit set in the featuresState, the driver will return the
* current state of this specific feature and whatever data that are
* associated with the feature in the data field or perform whatever
* action needed indicates in the data field.
*/
if (f.feat.fValue == 0) {
f.feat.fBits.largeLBA =
(sc->flags & AAC_FLAGS_LBA_64BIT) ? 1 : 0;
/* TODO: In the future, add other features state here as well */
} else {
if (f.feat.fBits.largeLBA)
f.feat.fBits.largeLBA =
(sc->flags & AAC_FLAGS_LBA_64BIT) ? 1 : 0;
/* TODO: Add other features state and data in the future */
}
error = copyout(&f, uptr, sizeof (f));
return (error);
}
/*
* Give the userland some information about the container. The AAC arch
* expects the driver to be a SCSI passthrough type driver, so it expects
* the containers to have b:t:l numbers. Fake it.
*/
static int
aac_query_disk(struct aac_softc *sc, caddr_t uptr)
{
struct aac_query_disk query_disk;
struct aac_container *co;
struct aac_disk *disk;
int error, id;
fwprintf(sc, HBA_FLAGS_DBG_FUNCTION_ENTRY_B, "");
disk = NULL;
error = copyin(uptr, (caddr_t)&query_disk,
sizeof(struct aac_query_disk));
if (error)
return (error);
id = query_disk.ContainerNumber;
if (id == -1)
return (EINVAL);
mtx_lock(&sc->aac_container_lock);
TAILQ_FOREACH(co, &sc->aac_container_tqh, co_link) {
if (co->co_mntobj.ObjectId == id)
break;
}
if (co == NULL) {
query_disk.Valid = 0;
query_disk.Locked = 0;
query_disk.Deleted = 1; /* XXX is this right? */
} else {
disk = device_get_softc(co->co_disk);
query_disk.Valid = 1;
query_disk.Locked =
(disk->ad_flags & AAC_DISK_OPEN) ? 1 : 0;
query_disk.Deleted = 0;
query_disk.Bus = device_get_unit(sc->aac_dev);
query_disk.Target = disk->unit;
query_disk.Lun = 0;
query_disk.UnMapped = 0;
sprintf(&query_disk.diskDeviceName[0], "%s%d",
disk->ad_disk->d_name, disk->ad_disk->d_unit);
}
mtx_unlock(&sc->aac_container_lock);
error = copyout((caddr_t)&query_disk, uptr,
sizeof(struct aac_query_disk));
return (error);
}
static void
aac_get_bus_info(struct aac_softc *sc)
{
struct aac_fib *fib;
struct aac_ctcfg *c_cmd;
struct aac_ctcfg_resp *c_resp;
struct aac_vmioctl *vmi;
struct aac_vmi_businf_resp *vmi_resp;
struct aac_getbusinf businfo;
struct aac_sim *caminf;
device_t child;
int i, found, error;
mtx_lock(&sc->aac_io_lock);
aac_alloc_sync_fib(sc, &fib);
c_cmd = (struct aac_ctcfg *)&fib->data[0];
bzero(c_cmd, sizeof(struct aac_ctcfg));
c_cmd->Command = VM_ContainerConfig;
c_cmd->cmd = CT_GET_SCSI_METHOD;
c_cmd->param = 0;
error = aac_sync_fib(sc, ContainerCommand, 0, fib,
sizeof(struct aac_ctcfg));
if (error) {
device_printf(sc->aac_dev, "Error %d sending "
"VM_ContainerConfig command\n", error);
aac_release_sync_fib(sc);
mtx_unlock(&sc->aac_io_lock);
return;
}
c_resp = (struct aac_ctcfg_resp *)&fib->data[0];
if (c_resp->Status != ST_OK) {
device_printf(sc->aac_dev, "VM_ContainerConfig returned 0x%x\n",
c_resp->Status);
aac_release_sync_fib(sc);
mtx_unlock(&sc->aac_io_lock);
return;
}
sc->scsi_method_id = c_resp->param;
vmi = (struct aac_vmioctl *)&fib->data[0];
bzero(vmi, sizeof(struct aac_vmioctl));
vmi->Command = VM_Ioctl;
vmi->ObjType = FT_DRIVE;
vmi->MethId = sc->scsi_method_id;
vmi->ObjId = 0;
vmi->IoctlCmd = GetBusInfo;
error = aac_sync_fib(sc, ContainerCommand, 0, fib,
sizeof(struct aac_vmi_businf_resp));
if (error) {
device_printf(sc->aac_dev, "Error %d sending VMIoctl command\n",
error);
aac_release_sync_fib(sc);
mtx_unlock(&sc->aac_io_lock);
return;
}
vmi_resp = (struct aac_vmi_businf_resp *)&fib->data[0];
if (vmi_resp->Status != ST_OK) {
device_printf(sc->aac_dev, "VM_Ioctl returned %d\n",
vmi_resp->Status);
aac_release_sync_fib(sc);
mtx_unlock(&sc->aac_io_lock);
return;
}
bcopy(&vmi_resp->BusInf, &businfo, sizeof(struct aac_getbusinf));
aac_release_sync_fib(sc);
mtx_unlock(&sc->aac_io_lock);
found = 0;
for (i = 0; i < businfo.BusCount; i++) {
if (businfo.BusValid[i] != AAC_BUS_VALID)
continue;
caminf = (struct aac_sim *)malloc( sizeof(struct aac_sim),
M_AACBUF, M_NOWAIT | M_ZERO);
if (caminf == NULL) {
device_printf(sc->aac_dev,
"No memory to add passthrough bus %d\n", i);
break;
}
child = device_add_child(sc->aac_dev, "aacp", -1);
if (child == NULL) {
device_printf(sc->aac_dev,
"device_add_child failed for passthrough bus %d\n",
i);
free(caminf, M_AACBUF);
break;
}
caminf->TargetsPerBus = businfo.TargetsPerBus;
caminf->BusNumber = i;
caminf->InitiatorBusId = businfo.InitiatorBusId[i];
caminf->aac_sc = sc;
caminf->sim_dev = child;
device_set_ivars(child, caminf);
device_set_desc(child, "SCSI Passthrough Bus");
TAILQ_INSERT_TAIL(&sc->aac_sim_tqh, caminf, sim_link);
found = 1;
}
if (found)
bus_generic_attach(sc->aac_dev);
}