linux/drivers/scsi/esas2r/esas2r_ioctl.c
Bradley Grove 9588d24e36 [SCSI] esas2r: Directly call kernel functions for atomic bit operations
Previously the code embedded the kernel's test_bit/clear_bit
functions in wrappers that accepted u32 parameters.  The
wrapper cast these parameters to longs before passing them
to the kernel's bit functions.   This did not work properly
on platforms with 64-bit longs.

Signed-off-by: Bradley Grove <bgrove@attotech.com>
Signed-off-by: James Bottomley <JBottomley@Parallels.com>
2013-10-25 09:58:59 +01:00

2111 lines
51 KiB
C

/*
* linux/drivers/scsi/esas2r/esas2r_ioctl.c
* For use with ATTO ExpressSAS R6xx SAS/SATA RAID controllers
*
* Copyright (c) 2001-2013 ATTO Technology, Inc.
* (mailto:linuxdrivers@attotech.com)
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* NO WARRANTY
* THE PROGRAM IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OR
* CONDITIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED INCLUDING, WITHOUT
* LIMITATION, ANY WARRANTIES OR CONDITIONS OF TITLE, NON-INFRINGEMENT,
* MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Each Recipient is
* solely responsible for determining the appropriateness of using and
* distributing the Program and assumes all risks associated with its
* exercise of rights under this Agreement, including but not limited to
* the risks and costs of program errors, damage to or loss of data,
* programs or equipment, and unavailability or interruption of operations.
*
* DISCLAIMER OF LIABILITY
* NEITHER RECIPIENT NOR ANY CONTRIBUTORS SHALL HAVE ANY LIABILITY FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING WITHOUT LIMITATION LOST PROFITS), 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 OR DISTRIBUTION OF THE PROGRAM OR THE EXERCISE OF ANY RIGHTS GRANTED
* HEREUNDER, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGES
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301,
* USA.
*/
#include "esas2r.h"
/*
* Buffered ioctl handlers. A buffered ioctl is one which requires that we
* allocate a DMA-able memory area to communicate with the firmware. In
* order to prevent continually allocating and freeing consistent memory,
* we will allocate a global buffer the first time we need it and re-use
* it for subsequent ioctl calls that require it.
*/
u8 *esas2r_buffered_ioctl;
dma_addr_t esas2r_buffered_ioctl_addr;
u32 esas2r_buffered_ioctl_size;
struct pci_dev *esas2r_buffered_ioctl_pcid;
static DEFINE_SEMAPHORE(buffered_ioctl_semaphore);
typedef int (*BUFFERED_IOCTL_CALLBACK)(struct esas2r_adapter *,
struct esas2r_request *,
struct esas2r_sg_context *,
void *);
typedef void (*BUFFERED_IOCTL_DONE_CALLBACK)(struct esas2r_adapter *,
struct esas2r_request *, void *);
struct esas2r_buffered_ioctl {
struct esas2r_adapter *a;
void *ioctl;
u32 length;
u32 control_code;
u32 offset;
BUFFERED_IOCTL_CALLBACK
callback;
void *context;
BUFFERED_IOCTL_DONE_CALLBACK
done_callback;
void *done_context;
};
static void complete_fm_api_req(struct esas2r_adapter *a,
struct esas2r_request *rq)
{
a->fm_api_command_done = 1;
wake_up_interruptible(&a->fm_api_waiter);
}
/* Callbacks for building scatter/gather lists for FM API requests */
static u32 get_physaddr_fm_api(struct esas2r_sg_context *sgc, u64 *addr)
{
struct esas2r_adapter *a = (struct esas2r_adapter *)sgc->adapter;
int offset = sgc->cur_offset - a->save_offset;
(*addr) = a->firmware.phys + offset;
return a->firmware.orig_len - offset;
}
static u32 get_physaddr_fm_api_header(struct esas2r_sg_context *sgc, u64 *addr)
{
struct esas2r_adapter *a = (struct esas2r_adapter *)sgc->adapter;
int offset = sgc->cur_offset - a->save_offset;
(*addr) = a->firmware.header_buff_phys + offset;
return sizeof(struct esas2r_flash_img) - offset;
}
/* Handle EXPRESS_IOCTL_RW_FIRMWARE ioctl with img_type = FW_IMG_FM_API. */
static void do_fm_api(struct esas2r_adapter *a, struct esas2r_flash_img *fi)
{
struct esas2r_request *rq;
if (down_interruptible(&a->fm_api_semaphore)) {
fi->status = FI_STAT_BUSY;
return;
}
rq = esas2r_alloc_request(a);
if (rq == NULL) {
up(&a->fm_api_semaphore);
fi->status = FI_STAT_BUSY;
return;
}
if (fi == &a->firmware.header) {
a->firmware.header_buff = dma_alloc_coherent(&a->pcid->dev,
(size_t)sizeof(
struct
esas2r_flash_img),
(dma_addr_t *)&a->
firmware.
header_buff_phys,
GFP_KERNEL);
if (a->firmware.header_buff == NULL) {
esas2r_debug("failed to allocate header buffer!");
fi->status = FI_STAT_BUSY;
return;
}
memcpy(a->firmware.header_buff, fi,
sizeof(struct esas2r_flash_img));
a->save_offset = a->firmware.header_buff;
a->fm_api_sgc.get_phys_addr =
(PGETPHYSADDR)get_physaddr_fm_api_header;
} else {
a->save_offset = (u8 *)fi;
a->fm_api_sgc.get_phys_addr =
(PGETPHYSADDR)get_physaddr_fm_api;
}
rq->comp_cb = complete_fm_api_req;
a->fm_api_command_done = 0;
a->fm_api_sgc.cur_offset = a->save_offset;
if (!esas2r_fm_api(a, (struct esas2r_flash_img *)a->save_offset, rq,
&a->fm_api_sgc))
goto all_done;
/* Now wait around for it to complete. */
while (!a->fm_api_command_done)
wait_event_interruptible(a->fm_api_waiter,
a->fm_api_command_done);
all_done:
if (fi == &a->firmware.header) {
memcpy(fi, a->firmware.header_buff,
sizeof(struct esas2r_flash_img));
dma_free_coherent(&a->pcid->dev,
(size_t)sizeof(struct esas2r_flash_img),
a->firmware.header_buff,
(dma_addr_t)a->firmware.header_buff_phys);
}
up(&a->fm_api_semaphore);
esas2r_free_request(a, (struct esas2r_request *)rq);
return;
}
static void complete_nvr_req(struct esas2r_adapter *a,
struct esas2r_request *rq)
{
a->nvram_command_done = 1;
wake_up_interruptible(&a->nvram_waiter);
}
/* Callback for building scatter/gather lists for buffered ioctls */
static u32 get_physaddr_buffered_ioctl(struct esas2r_sg_context *sgc,
u64 *addr)
{
int offset = (u8 *)sgc->cur_offset - esas2r_buffered_ioctl;
(*addr) = esas2r_buffered_ioctl_addr + offset;
return esas2r_buffered_ioctl_size - offset;
}
static void complete_buffered_ioctl_req(struct esas2r_adapter *a,
struct esas2r_request *rq)
{
a->buffered_ioctl_done = 1;
wake_up_interruptible(&a->buffered_ioctl_waiter);
}
static u8 handle_buffered_ioctl(struct esas2r_buffered_ioctl *bi)
{
struct esas2r_adapter *a = bi->a;
struct esas2r_request *rq;
struct esas2r_sg_context sgc;
u8 result = IOCTL_SUCCESS;
if (down_interruptible(&buffered_ioctl_semaphore))
return IOCTL_OUT_OF_RESOURCES;
/* allocate a buffer or use the existing buffer. */
if (esas2r_buffered_ioctl) {
if (esas2r_buffered_ioctl_size < bi->length) {
/* free the too-small buffer and get a new one */
dma_free_coherent(&a->pcid->dev,
(size_t)esas2r_buffered_ioctl_size,
esas2r_buffered_ioctl,
esas2r_buffered_ioctl_addr);
goto allocate_buffer;
}
} else {
allocate_buffer:
esas2r_buffered_ioctl_size = bi->length;
esas2r_buffered_ioctl_pcid = a->pcid;
esas2r_buffered_ioctl = dma_alloc_coherent(&a->pcid->dev,
(size_t)
esas2r_buffered_ioctl_size,
&
esas2r_buffered_ioctl_addr,
GFP_KERNEL);
}
if (!esas2r_buffered_ioctl) {
esas2r_log(ESAS2R_LOG_CRIT,
"could not allocate %d bytes of consistent memory "
"for a buffered ioctl!",
bi->length);
esas2r_debug("buffered ioctl alloc failure");
result = IOCTL_OUT_OF_RESOURCES;
goto exit_cleanly;
}
memcpy(esas2r_buffered_ioctl, bi->ioctl, bi->length);
rq = esas2r_alloc_request(a);
if (rq == NULL) {
esas2r_log(ESAS2R_LOG_CRIT,
"could not allocate an internal request");
result = IOCTL_OUT_OF_RESOURCES;
esas2r_debug("buffered ioctl - no requests");
goto exit_cleanly;
}
a->buffered_ioctl_done = 0;
rq->comp_cb = complete_buffered_ioctl_req;
sgc.cur_offset = esas2r_buffered_ioctl + bi->offset;
sgc.get_phys_addr = (PGETPHYSADDR)get_physaddr_buffered_ioctl;
sgc.length = esas2r_buffered_ioctl_size;
if (!(*bi->callback)(a, rq, &sgc, bi->context)) {
/* completed immediately, no need to wait */
a->buffered_ioctl_done = 0;
goto free_andexit_cleanly;
}
/* now wait around for it to complete. */
while (!a->buffered_ioctl_done)
wait_event_interruptible(a->buffered_ioctl_waiter,
a->buffered_ioctl_done);
free_andexit_cleanly:
if (result == IOCTL_SUCCESS && bi->done_callback)
(*bi->done_callback)(a, rq, bi->done_context);
esas2r_free_request(a, rq);
exit_cleanly:
if (result == IOCTL_SUCCESS)
memcpy(bi->ioctl, esas2r_buffered_ioctl, bi->length);
up(&buffered_ioctl_semaphore);
return result;
}
/* SMP ioctl support */
static int smp_ioctl_callback(struct esas2r_adapter *a,
struct esas2r_request *rq,
struct esas2r_sg_context *sgc, void *context)
{
struct atto_ioctl_smp *si =
(struct atto_ioctl_smp *)esas2r_buffered_ioctl;
esas2r_sgc_init(sgc, a, rq, rq->vrq->ioctl.sge);
esas2r_build_ioctl_req(a, rq, sgc->length, VDA_IOCTL_SMP);
if (!esas2r_build_sg_list(a, rq, sgc)) {
si->status = ATTO_STS_OUT_OF_RSRC;
return false;
}
esas2r_start_request(a, rq);
return true;
}
static u8 handle_smp_ioctl(struct esas2r_adapter *a, struct atto_ioctl_smp *si)
{
struct esas2r_buffered_ioctl bi;
memset(&bi, 0, sizeof(bi));
bi.a = a;
bi.ioctl = si;
bi.length = sizeof(struct atto_ioctl_smp)
+ le32_to_cpu(si->req_length)
+ le32_to_cpu(si->rsp_length);
bi.offset = 0;
bi.callback = smp_ioctl_callback;
return handle_buffered_ioctl(&bi);
}
/* CSMI ioctl support */
static void esas2r_csmi_ioctl_tunnel_comp_cb(struct esas2r_adapter *a,
struct esas2r_request *rq)
{
rq->target_id = le16_to_cpu(rq->func_rsp.ioctl_rsp.csmi.target_id);
rq->vrq->scsi.flags |= cpu_to_le32(rq->func_rsp.ioctl_rsp.csmi.lun);
/* Now call the original completion callback. */
(*rq->aux_req_cb)(a, rq);
}
/* Tunnel a CSMI IOCTL to the back end driver for processing. */
static bool csmi_ioctl_tunnel(struct esas2r_adapter *a,
union atto_ioctl_csmi *ci,
struct esas2r_request *rq,
struct esas2r_sg_context *sgc,
u32 ctrl_code,
u16 target_id)
{
struct atto_vda_ioctl_req *ioctl = &rq->vrq->ioctl;
if (test_bit(AF_DEGRADED_MODE, &a->flags))
return false;
esas2r_sgc_init(sgc, a, rq, rq->vrq->ioctl.sge);
esas2r_build_ioctl_req(a, rq, sgc->length, VDA_IOCTL_CSMI);
ioctl->csmi.ctrl_code = cpu_to_le32(ctrl_code);
ioctl->csmi.target_id = cpu_to_le16(target_id);
ioctl->csmi.lun = (u8)le32_to_cpu(rq->vrq->scsi.flags);
/*
* Always usurp the completion callback since the interrupt callback
* mechanism may be used.
*/
rq->aux_req_cx = ci;
rq->aux_req_cb = rq->comp_cb;
rq->comp_cb = esas2r_csmi_ioctl_tunnel_comp_cb;
if (!esas2r_build_sg_list(a, rq, sgc))
return false;
esas2r_start_request(a, rq);
return true;
}
static bool check_lun(struct scsi_lun lun)
{
bool result;
result = ((lun.scsi_lun[7] == 0) &&
(lun.scsi_lun[6] == 0) &&
(lun.scsi_lun[5] == 0) &&
(lun.scsi_lun[4] == 0) &&
(lun.scsi_lun[3] == 0) &&
(lun.scsi_lun[2] == 0) &&
/* Byte 1 is intentionally skipped */
(lun.scsi_lun[0] == 0));
return result;
}
static int csmi_ioctl_callback(struct esas2r_adapter *a,
struct esas2r_request *rq,
struct esas2r_sg_context *sgc, void *context)
{
struct atto_csmi *ci = (struct atto_csmi *)context;
union atto_ioctl_csmi *ioctl_csmi =
(union atto_ioctl_csmi *)esas2r_buffered_ioctl;
u8 path = 0;
u8 tid = 0;
u8 lun = 0;
u32 sts = CSMI_STS_SUCCESS;
struct esas2r_target *t;
unsigned long flags;
if (ci->control_code == CSMI_CC_GET_DEV_ADDR) {
struct atto_csmi_get_dev_addr *gda = &ci->data.dev_addr;
path = gda->path_id;
tid = gda->target_id;
lun = gda->lun;
} else if (ci->control_code == CSMI_CC_TASK_MGT) {
struct atto_csmi_task_mgmt *tm = &ci->data.tsk_mgt;
path = tm->path_id;
tid = tm->target_id;
lun = tm->lun;
}
if (path > 0) {
rq->func_rsp.ioctl_rsp.csmi.csmi_status = cpu_to_le32(
CSMI_STS_INV_PARAM);
return false;
}
rq->target_id = tid;
rq->vrq->scsi.flags |= cpu_to_le32(lun);
switch (ci->control_code) {
case CSMI_CC_GET_DRVR_INFO:
{
struct atto_csmi_get_driver_info *gdi = &ioctl_csmi->drvr_info;
strcpy(gdi->description, esas2r_get_model_name(a));
gdi->csmi_major_rev = CSMI_MAJOR_REV;
gdi->csmi_minor_rev = CSMI_MINOR_REV;
break;
}
case CSMI_CC_GET_CNTLR_CFG:
{
struct atto_csmi_get_cntlr_cfg *gcc = &ioctl_csmi->cntlr_cfg;
gcc->base_io_addr = 0;
pci_read_config_dword(a->pcid, PCI_BASE_ADDRESS_2,
&gcc->base_memaddr_lo);
pci_read_config_dword(a->pcid, PCI_BASE_ADDRESS_3,
&gcc->base_memaddr_hi);
gcc->board_id = MAKEDWORD(a->pcid->subsystem_device,
a->pcid->subsystem_vendor);
gcc->slot_num = CSMI_SLOT_NUM_UNKNOWN;
gcc->cntlr_class = CSMI_CNTLR_CLASS_HBA;
gcc->io_bus_type = CSMI_BUS_TYPE_PCI;
gcc->pci_addr.bus_num = a->pcid->bus->number;
gcc->pci_addr.device_num = PCI_SLOT(a->pcid->devfn);
gcc->pci_addr.function_num = PCI_FUNC(a->pcid->devfn);
memset(gcc->serial_num, 0, sizeof(gcc->serial_num));
gcc->major_rev = LOBYTE(LOWORD(a->fw_version));
gcc->minor_rev = HIBYTE(LOWORD(a->fw_version));
gcc->build_rev = LOBYTE(HIWORD(a->fw_version));
gcc->release_rev = HIBYTE(HIWORD(a->fw_version));
gcc->bios_major_rev = HIBYTE(HIWORD(a->flash_ver));
gcc->bios_minor_rev = LOBYTE(HIWORD(a->flash_ver));
gcc->bios_build_rev = LOWORD(a->flash_ver);
if (test_bit(AF2_THUNDERLINK, &a->flags2))
gcc->cntlr_flags = CSMI_CNTLRF_SAS_HBA
| CSMI_CNTLRF_SATA_HBA;
else
gcc->cntlr_flags = CSMI_CNTLRF_SAS_RAID
| CSMI_CNTLRF_SATA_RAID;
gcc->rrom_major_rev = 0;
gcc->rrom_minor_rev = 0;
gcc->rrom_build_rev = 0;
gcc->rrom_release_rev = 0;
gcc->rrom_biosmajor_rev = 0;
gcc->rrom_biosminor_rev = 0;
gcc->rrom_biosbuild_rev = 0;
gcc->rrom_biosrelease_rev = 0;
break;
}
case CSMI_CC_GET_CNTLR_STS:
{
struct atto_csmi_get_cntlr_sts *gcs = &ioctl_csmi->cntlr_sts;
if (test_bit(AF_DEGRADED_MODE, &a->flags))
gcs->status = CSMI_CNTLR_STS_FAILED;
else
gcs->status = CSMI_CNTLR_STS_GOOD;
gcs->offline_reason = CSMI_OFFLINE_NO_REASON;
break;
}
case CSMI_CC_FW_DOWNLOAD:
case CSMI_CC_GET_RAID_INFO:
case CSMI_CC_GET_RAID_CFG:
sts = CSMI_STS_BAD_CTRL_CODE;
break;
case CSMI_CC_SMP_PASSTHRU:
case CSMI_CC_SSP_PASSTHRU:
case CSMI_CC_STP_PASSTHRU:
case CSMI_CC_GET_PHY_INFO:
case CSMI_CC_SET_PHY_INFO:
case CSMI_CC_GET_LINK_ERRORS:
case CSMI_CC_GET_SATA_SIG:
case CSMI_CC_GET_CONN_INFO:
case CSMI_CC_PHY_CTRL:
if (!csmi_ioctl_tunnel(a, ioctl_csmi, rq, sgc,
ci->control_code,
ESAS2R_TARG_ID_INV)) {
sts = CSMI_STS_FAILED;
break;
}
return true;
case CSMI_CC_GET_SCSI_ADDR:
{
struct atto_csmi_get_scsi_addr *gsa = &ioctl_csmi->scsi_addr;
struct scsi_lun lun;
memcpy(&lun, gsa->sas_lun, sizeof(struct scsi_lun));
if (!check_lun(lun)) {
sts = CSMI_STS_NO_SCSI_ADDR;
break;
}
/* make sure the device is present */
spin_lock_irqsave(&a->mem_lock, flags);
t = esas2r_targ_db_find_by_sas_addr(a, (u64 *)gsa->sas_addr);
spin_unlock_irqrestore(&a->mem_lock, flags);
if (t == NULL) {
sts = CSMI_STS_NO_SCSI_ADDR;
break;
}
gsa->host_index = 0xFF;
gsa->lun = gsa->sas_lun[1];
rq->target_id = esas2r_targ_get_id(t, a);
break;
}
case CSMI_CC_GET_DEV_ADDR:
{
struct atto_csmi_get_dev_addr *gda = &ioctl_csmi->dev_addr;
/* make sure the target is present */
t = a->targetdb + rq->target_id;
if (t >= a->targetdb_end
|| t->target_state != TS_PRESENT
|| t->sas_addr == 0) {
sts = CSMI_STS_NO_DEV_ADDR;
break;
}
/* fill in the result */
*(u64 *)gda->sas_addr = t->sas_addr;
memset(gda->sas_lun, 0, sizeof(gda->sas_lun));
gda->sas_lun[1] = (u8)le32_to_cpu(rq->vrq->scsi.flags);
break;
}
case CSMI_CC_TASK_MGT:
/* make sure the target is present */
t = a->targetdb + rq->target_id;
if (t >= a->targetdb_end
|| t->target_state != TS_PRESENT
|| !(t->flags & TF_PASS_THRU)) {
sts = CSMI_STS_NO_DEV_ADDR;
break;
}
if (!csmi_ioctl_tunnel(a, ioctl_csmi, rq, sgc,
ci->control_code,
t->phys_targ_id)) {
sts = CSMI_STS_FAILED;
break;
}
return true;
default:
sts = CSMI_STS_BAD_CTRL_CODE;
break;
}
rq->func_rsp.ioctl_rsp.csmi.csmi_status = cpu_to_le32(sts);
return false;
}
static void csmi_ioctl_done_callback(struct esas2r_adapter *a,
struct esas2r_request *rq, void *context)
{
struct atto_csmi *ci = (struct atto_csmi *)context;
union atto_ioctl_csmi *ioctl_csmi =
(union atto_ioctl_csmi *)esas2r_buffered_ioctl;
switch (ci->control_code) {
case CSMI_CC_GET_DRVR_INFO:
{
struct atto_csmi_get_driver_info *gdi =
&ioctl_csmi->drvr_info;
strcpy(gdi->name, ESAS2R_VERSION_STR);
gdi->major_rev = ESAS2R_MAJOR_REV;
gdi->minor_rev = ESAS2R_MINOR_REV;
gdi->build_rev = 0;
gdi->release_rev = 0;
break;
}
case CSMI_CC_GET_SCSI_ADDR:
{
struct atto_csmi_get_scsi_addr *gsa = &ioctl_csmi->scsi_addr;
if (le32_to_cpu(rq->func_rsp.ioctl_rsp.csmi.csmi_status) ==
CSMI_STS_SUCCESS) {
gsa->target_id = rq->target_id;
gsa->path_id = 0;
}
break;
}
}
ci->status = le32_to_cpu(rq->func_rsp.ioctl_rsp.csmi.csmi_status);
}
static u8 handle_csmi_ioctl(struct esas2r_adapter *a, struct atto_csmi *ci)
{
struct esas2r_buffered_ioctl bi;
memset(&bi, 0, sizeof(bi));
bi.a = a;
bi.ioctl = &ci->data;
bi.length = sizeof(union atto_ioctl_csmi);
bi.offset = 0;
bi.callback = csmi_ioctl_callback;
bi.context = ci;
bi.done_callback = csmi_ioctl_done_callback;
bi.done_context = ci;
return handle_buffered_ioctl(&bi);
}
/* ATTO HBA ioctl support */
/* Tunnel an ATTO HBA IOCTL to the back end driver for processing. */
static bool hba_ioctl_tunnel(struct esas2r_adapter *a,
struct atto_ioctl *hi,
struct esas2r_request *rq,
struct esas2r_sg_context *sgc)
{
esas2r_sgc_init(sgc, a, rq, rq->vrq->ioctl.sge);
esas2r_build_ioctl_req(a, rq, sgc->length, VDA_IOCTL_HBA);
if (!esas2r_build_sg_list(a, rq, sgc)) {
hi->status = ATTO_STS_OUT_OF_RSRC;
return false;
}
esas2r_start_request(a, rq);
return true;
}
static void scsi_passthru_comp_cb(struct esas2r_adapter *a,
struct esas2r_request *rq)
{
struct atto_ioctl *hi = (struct atto_ioctl *)rq->aux_req_cx;
struct atto_hba_scsi_pass_thru *spt = &hi->data.scsi_pass_thru;
u8 sts = ATTO_SPT_RS_FAILED;
spt->scsi_status = rq->func_rsp.scsi_rsp.scsi_stat;
spt->sense_length = rq->sense_len;
spt->residual_length =
le32_to_cpu(rq->func_rsp.scsi_rsp.residual_length);
switch (rq->req_stat) {
case RS_SUCCESS:
case RS_SCSI_ERROR:
sts = ATTO_SPT_RS_SUCCESS;
break;
case RS_UNDERRUN:
sts = ATTO_SPT_RS_UNDERRUN;
break;
case RS_OVERRUN:
sts = ATTO_SPT_RS_OVERRUN;
break;
case RS_SEL:
case RS_SEL2:
sts = ATTO_SPT_RS_NO_DEVICE;
break;
case RS_NO_LUN:
sts = ATTO_SPT_RS_NO_LUN;
break;
case RS_TIMEOUT:
sts = ATTO_SPT_RS_TIMEOUT;
break;
case RS_DEGRADED:
sts = ATTO_SPT_RS_DEGRADED;
break;
case RS_BUSY:
sts = ATTO_SPT_RS_BUSY;
break;
case RS_ABORTED:
sts = ATTO_SPT_RS_ABORTED;
break;
case RS_RESET:
sts = ATTO_SPT_RS_BUS_RESET;
break;
}
spt->req_status = sts;
/* Update the target ID to the next one present. */
spt->target_id =
esas2r_targ_db_find_next_present(a, (u16)spt->target_id);
/* Done, call the completion callback. */
(*rq->aux_req_cb)(a, rq);
}
static int hba_ioctl_callback(struct esas2r_adapter *a,
struct esas2r_request *rq,
struct esas2r_sg_context *sgc,
void *context)
{
struct atto_ioctl *hi = (struct atto_ioctl *)esas2r_buffered_ioctl;
hi->status = ATTO_STS_SUCCESS;
switch (hi->function) {
case ATTO_FUNC_GET_ADAP_INFO:
{
u8 *class_code = (u8 *)&a->pcid->class;
struct atto_hba_get_adapter_info *gai =
&hi->data.get_adap_info;
int pcie_cap_reg;
if (hi->flags & HBAF_TUNNEL) {
hi->status = ATTO_STS_UNSUPPORTED;
break;
}
if (hi->version > ATTO_VER_GET_ADAP_INFO0) {
hi->status = ATTO_STS_INV_VERSION;
hi->version = ATTO_VER_GET_ADAP_INFO0;
break;
}
memset(gai, 0, sizeof(*gai));
gai->pci.vendor_id = a->pcid->vendor;
gai->pci.device_id = a->pcid->device;
gai->pci.ss_vendor_id = a->pcid->subsystem_vendor;
gai->pci.ss_device_id = a->pcid->subsystem_device;
gai->pci.class_code[0] = class_code[0];
gai->pci.class_code[1] = class_code[1];
gai->pci.class_code[2] = class_code[2];
gai->pci.rev_id = a->pcid->revision;
gai->pci.bus_num = a->pcid->bus->number;
gai->pci.dev_num = PCI_SLOT(a->pcid->devfn);
gai->pci.func_num = PCI_FUNC(a->pcid->devfn);
pcie_cap_reg = pci_find_capability(a->pcid, PCI_CAP_ID_EXP);
if (pcie_cap_reg) {
u16 stat;
u32 caps;
pci_read_config_word(a->pcid,
pcie_cap_reg + PCI_EXP_LNKSTA,
&stat);
pci_read_config_dword(a->pcid,
pcie_cap_reg + PCI_EXP_LNKCAP,
&caps);
gai->pci.link_speed_curr =
(u8)(stat & PCI_EXP_LNKSTA_CLS);
gai->pci.link_speed_max =
(u8)(caps & PCI_EXP_LNKCAP_SLS);
gai->pci.link_width_curr =
(u8)((stat & PCI_EXP_LNKSTA_NLW)
>> PCI_EXP_LNKSTA_NLW_SHIFT);
gai->pci.link_width_max =
(u8)((caps & PCI_EXP_LNKCAP_MLW)
>> 4);
}
gai->pci.msi_vector_cnt = 1;
if (a->pcid->msix_enabled)
gai->pci.interrupt_mode = ATTO_GAI_PCIIM_MSIX;
else if (a->pcid->msi_enabled)
gai->pci.interrupt_mode = ATTO_GAI_PCIIM_MSI;
else
gai->pci.interrupt_mode = ATTO_GAI_PCIIM_LEGACY;
gai->adap_type = ATTO_GAI_AT_ESASRAID2;
if (test_bit(AF2_THUNDERLINK, &a->flags2))
gai->adap_type = ATTO_GAI_AT_TLSASHBA;
if (test_bit(AF_DEGRADED_MODE, &a->flags))
gai->adap_flags |= ATTO_GAI_AF_DEGRADED;
gai->adap_flags |= ATTO_GAI_AF_SPT_SUPP |
ATTO_GAI_AF_DEVADDR_SUPP;
if (a->pcid->subsystem_device == ATTO_ESAS_R60F
|| a->pcid->subsystem_device == ATTO_ESAS_R608
|| a->pcid->subsystem_device == ATTO_ESAS_R644
|| a->pcid->subsystem_device == ATTO_TSSC_3808E)
gai->adap_flags |= ATTO_GAI_AF_VIRT_SES;
gai->num_ports = ESAS2R_NUM_PHYS;
gai->num_phys = ESAS2R_NUM_PHYS;
strcpy(gai->firmware_rev, a->fw_rev);
strcpy(gai->flash_rev, a->flash_rev);
strcpy(gai->model_name_short, esas2r_get_model_name_short(a));
strcpy(gai->model_name, esas2r_get_model_name(a));
gai->num_targets = ESAS2R_MAX_TARGETS;
gai->num_busses = 1;
gai->num_targsper_bus = gai->num_targets;
gai->num_lunsper_targ = 256;
if (a->pcid->subsystem_device == ATTO_ESAS_R6F0
|| a->pcid->subsystem_device == ATTO_ESAS_R60F)
gai->num_connectors = 4;
else
gai->num_connectors = 2;
gai->adap_flags2 |= ATTO_GAI_AF2_ADAP_CTRL_SUPP;
gai->num_targets_backend = a->num_targets_backend;
gai->tunnel_flags = a->ioctl_tunnel
& (ATTO_GAI_TF_MEM_RW
| ATTO_GAI_TF_TRACE
| ATTO_GAI_TF_SCSI_PASS_THRU
| ATTO_GAI_TF_GET_DEV_ADDR
| ATTO_GAI_TF_PHY_CTRL
| ATTO_GAI_TF_CONN_CTRL
| ATTO_GAI_TF_GET_DEV_INFO);
break;
}
case ATTO_FUNC_GET_ADAP_ADDR:
{
struct atto_hba_get_adapter_address *gaa =
&hi->data.get_adap_addr;
if (hi->flags & HBAF_TUNNEL) {
hi->status = ATTO_STS_UNSUPPORTED;
break;
}
if (hi->version > ATTO_VER_GET_ADAP_ADDR0) {
hi->status = ATTO_STS_INV_VERSION;
hi->version = ATTO_VER_GET_ADAP_ADDR0;
} else if (gaa->addr_type == ATTO_GAA_AT_PORT
|| gaa->addr_type == ATTO_GAA_AT_NODE) {
if (gaa->addr_type == ATTO_GAA_AT_PORT
&& gaa->port_id >= ESAS2R_NUM_PHYS) {
hi->status = ATTO_STS_NOT_APPL;
} else {
memcpy((u64 *)gaa->address,
&a->nvram->sas_addr[0], sizeof(u64));
gaa->addr_len = sizeof(u64);
}
} else {
hi->status = ATTO_STS_INV_PARAM;
}
break;
}
case ATTO_FUNC_MEM_RW:
{
if (hi->flags & HBAF_TUNNEL) {
if (hba_ioctl_tunnel(a, hi, rq, sgc))
return true;
break;
}
hi->status = ATTO_STS_UNSUPPORTED;
break;
}
case ATTO_FUNC_TRACE:
{
struct atto_hba_trace *trc = &hi->data.trace;
if (hi->flags & HBAF_TUNNEL) {
if (hba_ioctl_tunnel(a, hi, rq, sgc))
return true;
break;
}
if (hi->version > ATTO_VER_TRACE1) {
hi->status = ATTO_STS_INV_VERSION;
hi->version = ATTO_VER_TRACE1;
break;
}
if (trc->trace_type == ATTO_TRC_TT_FWCOREDUMP
&& hi->version >= ATTO_VER_TRACE1) {
if (trc->trace_func == ATTO_TRC_TF_UPLOAD) {
u32 len = hi->data_length;
u32 offset = trc->current_offset;
u32 total_len = ESAS2R_FWCOREDUMP_SZ;
/* Size is zero if a core dump isn't present */
if (!test_bit(AF2_COREDUMP_SAVED, &a->flags2))
total_len = 0;
if (len > total_len)
len = total_len;
if (offset >= total_len
|| offset + len > total_len
|| len == 0) {
hi->status = ATTO_STS_INV_PARAM;
break;
}
memcpy(trc + 1,
a->fw_coredump_buff + offset,
len);
hi->data_length = len;
} else if (trc->trace_func == ATTO_TRC_TF_RESET) {
memset(a->fw_coredump_buff, 0,
ESAS2R_FWCOREDUMP_SZ);
clear_bit(AF2_COREDUMP_SAVED, &a->flags2);
} else if (trc->trace_func != ATTO_TRC_TF_GET_INFO) {
hi->status = ATTO_STS_UNSUPPORTED;
break;
}
/* Always return all the info we can. */
trc->trace_mask = 0;
trc->current_offset = 0;
trc->total_length = ESAS2R_FWCOREDUMP_SZ;
/* Return zero length buffer if core dump not present */
if (!test_bit(AF2_COREDUMP_SAVED, &a->flags2))
trc->total_length = 0;
} else {
hi->status = ATTO_STS_UNSUPPORTED;
}
break;
}
case ATTO_FUNC_SCSI_PASS_THRU:
{
struct atto_hba_scsi_pass_thru *spt = &hi->data.scsi_pass_thru;
struct scsi_lun lun;
memcpy(&lun, spt->lun, sizeof(struct scsi_lun));
if (hi->flags & HBAF_TUNNEL) {
if (hba_ioctl_tunnel(a, hi, rq, sgc))
return true;
break;
}
if (hi->version > ATTO_VER_SCSI_PASS_THRU0) {
hi->status = ATTO_STS_INV_VERSION;
hi->version = ATTO_VER_SCSI_PASS_THRU0;
break;
}
if (spt->target_id >= ESAS2R_MAX_TARGETS || !check_lun(lun)) {
hi->status = ATTO_STS_INV_PARAM;
break;
}
esas2r_sgc_init(sgc, a, rq, NULL);
sgc->length = hi->data_length;
sgc->cur_offset += offsetof(struct atto_ioctl, data.byte)
+ sizeof(struct atto_hba_scsi_pass_thru);
/* Finish request initialization */
rq->target_id = (u16)spt->target_id;
rq->vrq->scsi.flags |= cpu_to_le32(spt->lun[1]);
memcpy(rq->vrq->scsi.cdb, spt->cdb, 16);
rq->vrq->scsi.length = cpu_to_le32(hi->data_length);
rq->sense_len = spt->sense_length;
rq->sense_buf = (u8 *)spt->sense_data;
/* NOTE: we ignore spt->timeout */
/*
* always usurp the completion callback since the interrupt
* callback mechanism may be used.
*/
rq->aux_req_cx = hi;
rq->aux_req_cb = rq->comp_cb;
rq->comp_cb = scsi_passthru_comp_cb;
if (spt->flags & ATTO_SPTF_DATA_IN) {
rq->vrq->scsi.flags |= cpu_to_le32(FCP_CMND_RDD);
} else if (spt->flags & ATTO_SPTF_DATA_OUT) {
rq->vrq->scsi.flags |= cpu_to_le32(FCP_CMND_WRD);
} else {
if (sgc->length) {
hi->status = ATTO_STS_INV_PARAM;
break;
}
}
if (spt->flags & ATTO_SPTF_ORDERED_Q)
rq->vrq->scsi.flags |=
cpu_to_le32(FCP_CMND_TA_ORDRD_Q);
else if (spt->flags & ATTO_SPTF_HEAD_OF_Q)
rq->vrq->scsi.flags |= cpu_to_le32(FCP_CMND_TA_HEAD_Q);
if (!esas2r_build_sg_list(a, rq, sgc)) {
hi->status = ATTO_STS_OUT_OF_RSRC;
break;
}
esas2r_start_request(a, rq);
return true;
}
case ATTO_FUNC_GET_DEV_ADDR:
{
struct atto_hba_get_device_address *gda =
&hi->data.get_dev_addr;
struct esas2r_target *t;
if (hi->flags & HBAF_TUNNEL) {
if (hba_ioctl_tunnel(a, hi, rq, sgc))
return true;
break;
}
if (hi->version > ATTO_VER_GET_DEV_ADDR0) {
hi->status = ATTO_STS_INV_VERSION;
hi->version = ATTO_VER_GET_DEV_ADDR0;
break;
}
if (gda->target_id >= ESAS2R_MAX_TARGETS) {
hi->status = ATTO_STS_INV_PARAM;
break;
}
t = a->targetdb + (u16)gda->target_id;
if (t->target_state != TS_PRESENT) {
hi->status = ATTO_STS_FAILED;
} else if (gda->addr_type == ATTO_GDA_AT_PORT) {
if (t->sas_addr == 0) {
hi->status = ATTO_STS_UNSUPPORTED;
} else {
*(u64 *)gda->address = t->sas_addr;
gda->addr_len = sizeof(u64);
}
} else if (gda->addr_type == ATTO_GDA_AT_NODE) {
hi->status = ATTO_STS_NOT_APPL;
} else {
hi->status = ATTO_STS_INV_PARAM;
}
/* update the target ID to the next one present. */
gda->target_id =
esas2r_targ_db_find_next_present(a,
(u16)gda->target_id);
break;
}
case ATTO_FUNC_PHY_CTRL:
case ATTO_FUNC_CONN_CTRL:
{
if (hba_ioctl_tunnel(a, hi, rq, sgc))
return true;
break;
}
case ATTO_FUNC_ADAP_CTRL:
{
struct atto_hba_adap_ctrl *ac = &hi->data.adap_ctrl;
if (hi->flags & HBAF_TUNNEL) {
hi->status = ATTO_STS_UNSUPPORTED;
break;
}
if (hi->version > ATTO_VER_ADAP_CTRL0) {
hi->status = ATTO_STS_INV_VERSION;
hi->version = ATTO_VER_ADAP_CTRL0;
break;
}
if (ac->adap_func == ATTO_AC_AF_HARD_RST) {
esas2r_reset_adapter(a);
} else if (ac->adap_func != ATTO_AC_AF_GET_STATE) {
hi->status = ATTO_STS_UNSUPPORTED;
break;
}
if (test_bit(AF_CHPRST_NEEDED, &a->flags))
ac->adap_state = ATTO_AC_AS_RST_SCHED;
else if (test_bit(AF_CHPRST_PENDING, &a->flags))
ac->adap_state = ATTO_AC_AS_RST_IN_PROG;
else if (test_bit(AF_DISC_PENDING, &a->flags))
ac->adap_state = ATTO_AC_AS_RST_DISC;
else if (test_bit(AF_DISABLED, &a->flags))
ac->adap_state = ATTO_AC_AS_DISABLED;
else if (test_bit(AF_DEGRADED_MODE, &a->flags))
ac->adap_state = ATTO_AC_AS_DEGRADED;
else
ac->adap_state = ATTO_AC_AS_OK;
break;
}
case ATTO_FUNC_GET_DEV_INFO:
{
struct atto_hba_get_device_info *gdi = &hi->data.get_dev_info;
struct esas2r_target *t;
if (hi->flags & HBAF_TUNNEL) {
if (hba_ioctl_tunnel(a, hi, rq, sgc))
return true;
break;
}
if (hi->version > ATTO_VER_GET_DEV_INFO0) {
hi->status = ATTO_STS_INV_VERSION;
hi->version = ATTO_VER_GET_DEV_INFO0;
break;
}
if (gdi->target_id >= ESAS2R_MAX_TARGETS) {
hi->status = ATTO_STS_INV_PARAM;
break;
}
t = a->targetdb + (u16)gdi->target_id;
/* update the target ID to the next one present. */
gdi->target_id =
esas2r_targ_db_find_next_present(a,
(u16)gdi->target_id);
if (t->target_state != TS_PRESENT) {
hi->status = ATTO_STS_FAILED;
break;
}
hi->status = ATTO_STS_UNSUPPORTED;
break;
}
default:
hi->status = ATTO_STS_INV_FUNC;
break;
}
return false;
}
static void hba_ioctl_done_callback(struct esas2r_adapter *a,
struct esas2r_request *rq, void *context)
{
struct atto_ioctl *ioctl_hba =
(struct atto_ioctl *)esas2r_buffered_ioctl;
esas2r_debug("hba_ioctl_done_callback %d", a->index);
if (ioctl_hba->function == ATTO_FUNC_GET_ADAP_INFO) {
struct atto_hba_get_adapter_info *gai =
&ioctl_hba->data.get_adap_info;
esas2r_debug("ATTO_FUNC_GET_ADAP_INFO");
gai->drvr_rev_major = ESAS2R_MAJOR_REV;
gai->drvr_rev_minor = ESAS2R_MINOR_REV;
strcpy(gai->drvr_rev_ascii, ESAS2R_VERSION_STR);
strcpy(gai->drvr_name, ESAS2R_DRVR_NAME);
gai->num_busses = 1;
gai->num_targsper_bus = ESAS2R_MAX_ID + 1;
gai->num_lunsper_targ = 1;
}
}
u8 handle_hba_ioctl(struct esas2r_adapter *a,
struct atto_ioctl *ioctl_hba)
{
struct esas2r_buffered_ioctl bi;
memset(&bi, 0, sizeof(bi));
bi.a = a;
bi.ioctl = ioctl_hba;
bi.length = sizeof(struct atto_ioctl) + ioctl_hba->data_length;
bi.callback = hba_ioctl_callback;
bi.context = NULL;
bi.done_callback = hba_ioctl_done_callback;
bi.done_context = NULL;
bi.offset = 0;
return handle_buffered_ioctl(&bi);
}
int esas2r_write_params(struct esas2r_adapter *a, struct esas2r_request *rq,
struct esas2r_sas_nvram *data)
{
int result = 0;
a->nvram_command_done = 0;
rq->comp_cb = complete_nvr_req;
if (esas2r_nvram_write(a, rq, data)) {
/* now wait around for it to complete. */
while (!a->nvram_command_done)
wait_event_interruptible(a->nvram_waiter,
a->nvram_command_done);
;
/* done, check the status. */
if (rq->req_stat == RS_SUCCESS)
result = 1;
}
return result;
}
/* This function only cares about ATTO-specific ioctls (atto_express_ioctl) */
int esas2r_ioctl_handler(void *hostdata, int cmd, void __user *arg)
{
struct atto_express_ioctl *ioctl = NULL;
struct esas2r_adapter *a;
struct esas2r_request *rq;
u16 code;
int err;
esas2r_log(ESAS2R_LOG_DEBG, "ioctl (%p, %x, %p)", hostdata, cmd, arg);
if ((arg == NULL)
|| (cmd < EXPRESS_IOCTL_MIN)
|| (cmd > EXPRESS_IOCTL_MAX))
return -ENOTSUPP;
if (!access_ok(VERIFY_WRITE, arg, sizeof(struct atto_express_ioctl))) {
esas2r_log(ESAS2R_LOG_WARN,
"ioctl_handler access_ok failed for cmd %d, "
"address %p", cmd,
arg);
return -EFAULT;
}
/* allocate a kernel memory buffer for the IOCTL data */
ioctl = kzalloc(sizeof(struct atto_express_ioctl), GFP_KERNEL);
if (ioctl == NULL) {
esas2r_log(ESAS2R_LOG_WARN,
"ioctl_handler kzalloc failed for %d bytes",
sizeof(struct atto_express_ioctl));
return -ENOMEM;
}
err = __copy_from_user(ioctl, arg, sizeof(struct atto_express_ioctl));
if (err != 0) {
esas2r_log(ESAS2R_LOG_WARN,
"copy_from_user didn't copy everything (err %d, cmd %d)",
err,
cmd);
kfree(ioctl);
return -EFAULT;
}
/* verify the signature */
if (memcmp(ioctl->header.signature,
EXPRESS_IOCTL_SIGNATURE,
EXPRESS_IOCTL_SIGNATURE_SIZE) != 0) {
esas2r_log(ESAS2R_LOG_WARN, "invalid signature");
kfree(ioctl);
return -ENOTSUPP;
}
/* assume success */
ioctl->header.return_code = IOCTL_SUCCESS;
err = 0;
/*
* handle EXPRESS_IOCTL_GET_CHANNELS
* without paying attention to channel
*/
if (cmd == EXPRESS_IOCTL_GET_CHANNELS) {
int i = 0, k = 0;
ioctl->data.chanlist.num_channels = 0;
while (i < MAX_ADAPTERS) {
if (esas2r_adapters[i]) {
ioctl->data.chanlist.num_channels++;
ioctl->data.chanlist.channel[k] = i;
k++;
}
i++;
}
goto ioctl_done;
}
/* get the channel */
if (ioctl->header.channel == 0xFF) {
a = (struct esas2r_adapter *)hostdata;
} else {
a = esas2r_adapters[ioctl->header.channel];
if (ioctl->header.channel >= MAX_ADAPTERS || (a == NULL)) {
ioctl->header.return_code = IOCTL_BAD_CHANNEL;
esas2r_log(ESAS2R_LOG_WARN, "bad channel value");
kfree(ioctl);
return -ENOTSUPP;
}
}
switch (cmd) {
case EXPRESS_IOCTL_RW_FIRMWARE:
if (ioctl->data.fwrw.img_type == FW_IMG_FM_API) {
err = esas2r_write_fw(a,
(char *)ioctl->data.fwrw.image,
0,
sizeof(struct
atto_express_ioctl));
if (err >= 0) {
err = esas2r_read_fw(a,
(char *)ioctl->data.fwrw.
image,
0,
sizeof(struct
atto_express_ioctl));
}
} else if (ioctl->data.fwrw.img_type == FW_IMG_FS_API) {
err = esas2r_write_fs(a,
(char *)ioctl->data.fwrw.image,
0,
sizeof(struct
atto_express_ioctl));
if (err >= 0) {
err = esas2r_read_fs(a,
(char *)ioctl->data.fwrw.
image,
0,
sizeof(struct
atto_express_ioctl));
}
} else {
ioctl->header.return_code = IOCTL_BAD_FLASH_IMGTYPE;
}
break;
case EXPRESS_IOCTL_READ_PARAMS:
memcpy(ioctl->data.prw.data_buffer, a->nvram,
sizeof(struct esas2r_sas_nvram));
ioctl->data.prw.code = 1;
break;
case EXPRESS_IOCTL_WRITE_PARAMS:
rq = esas2r_alloc_request(a);
if (rq == NULL) {
up(&a->nvram_semaphore);
ioctl->data.prw.code = 0;
break;
}
code = esas2r_write_params(a, rq,
(struct esas2r_sas_nvram *)ioctl->data.prw.data_buffer);
ioctl->data.prw.code = code;
esas2r_free_request(a, rq);
break;
case EXPRESS_IOCTL_DEFAULT_PARAMS:
esas2r_nvram_get_defaults(a,
(struct esas2r_sas_nvram *)ioctl->data.prw.data_buffer);
ioctl->data.prw.code = 1;
break;
case EXPRESS_IOCTL_CHAN_INFO:
ioctl->data.chaninfo.major_rev = ESAS2R_MAJOR_REV;
ioctl->data.chaninfo.minor_rev = ESAS2R_MINOR_REV;
ioctl->data.chaninfo.IRQ = a->pcid->irq;
ioctl->data.chaninfo.device_id = a->pcid->device;
ioctl->data.chaninfo.vendor_id = a->pcid->vendor;
ioctl->data.chaninfo.ven_dev_id = a->pcid->subsystem_device;
ioctl->data.chaninfo.revision_id = a->pcid->revision;
ioctl->data.chaninfo.pci_bus = a->pcid->bus->number;
ioctl->data.chaninfo.pci_dev_func = a->pcid->devfn;
ioctl->data.chaninfo.core_rev = 0;
ioctl->data.chaninfo.host_no = a->host->host_no;
ioctl->data.chaninfo.hbaapi_rev = 0;
break;
case EXPRESS_IOCTL_SMP:
ioctl->header.return_code = handle_smp_ioctl(a,
&ioctl->data.
ioctl_smp);
break;
case EXPRESS_CSMI:
ioctl->header.return_code =
handle_csmi_ioctl(a, &ioctl->data.csmi);
break;
case EXPRESS_IOCTL_HBA:
ioctl->header.return_code = handle_hba_ioctl(a,
&ioctl->data.
ioctl_hba);
break;
case EXPRESS_IOCTL_VDA:
err = esas2r_write_vda(a,
(char *)&ioctl->data.ioctl_vda,
0,
sizeof(struct atto_ioctl_vda) +
ioctl->data.ioctl_vda.data_length);
if (err >= 0) {
err = esas2r_read_vda(a,
(char *)&ioctl->data.ioctl_vda,
0,
sizeof(struct atto_ioctl_vda) +
ioctl->data.ioctl_vda.data_length);
}
break;
case EXPRESS_IOCTL_GET_MOD_INFO:
ioctl->data.modinfo.adapter = a;
ioctl->data.modinfo.pci_dev = a->pcid;
ioctl->data.modinfo.scsi_host = a->host;
ioctl->data.modinfo.host_no = a->host->host_no;
break;
default:
esas2r_debug("esas2r_ioctl invalid cmd %p!", cmd);
ioctl->header.return_code = IOCTL_ERR_INVCMD;
}
ioctl_done:
if (err < 0) {
esas2r_log(ESAS2R_LOG_WARN, "err %d on ioctl cmd %d", err,
cmd);
switch (err) {
case -ENOMEM:
case -EBUSY:
ioctl->header.return_code = IOCTL_OUT_OF_RESOURCES;
break;
case -ENOSYS:
case -EINVAL:
ioctl->header.return_code = IOCTL_INVALID_PARAM;
break;
}
ioctl->header.return_code = IOCTL_GENERAL_ERROR;
}
/* Always copy the buffer back, if only to pick up the status */
err = __copy_to_user(arg, ioctl, sizeof(struct atto_express_ioctl));
if (err != 0) {
esas2r_log(ESAS2R_LOG_WARN,
"ioctl_handler copy_to_user didn't copy "
"everything (err %d, cmd %d)", err,
cmd);
kfree(ioctl);
return -EFAULT;
}
kfree(ioctl);
return 0;
}
int esas2r_ioctl(struct scsi_device *sd, int cmd, void __user *arg)
{
return esas2r_ioctl_handler(sd->host->hostdata, cmd, arg);
}
static void free_fw_buffers(struct esas2r_adapter *a)
{
if (a->firmware.data) {
dma_free_coherent(&a->pcid->dev,
(size_t)a->firmware.orig_len,
a->firmware.data,
(dma_addr_t)a->firmware.phys);
a->firmware.data = NULL;
}
}
static int allocate_fw_buffers(struct esas2r_adapter *a, u32 length)
{
free_fw_buffers(a);
a->firmware.orig_len = length;
a->firmware.data = (u8 *)dma_alloc_coherent(&a->pcid->dev,
(size_t)length,
(dma_addr_t *)&a->firmware.
phys,
GFP_KERNEL);
if (!a->firmware.data) {
esas2r_debug("buffer alloc failed!");
return 0;
}
return 1;
}
/* Handle a call to read firmware. */
int esas2r_read_fw(struct esas2r_adapter *a, char *buf, long off, int count)
{
esas2r_trace_enter();
/* if the cached header is a status, simply copy it over and return. */
if (a->firmware.state == FW_STATUS_ST) {
int size = min_t(int, count, sizeof(a->firmware.header));
esas2r_trace_exit();
memcpy(buf, &a->firmware.header, size);
esas2r_debug("esas2r_read_fw: STATUS size %d", size);
return size;
}
/*
* if the cached header is a command, do it if at
* offset 0, otherwise copy the pieces.
*/
if (a->firmware.state == FW_COMMAND_ST) {
u32 length = a->firmware.header.length;
esas2r_trace_exit();
esas2r_debug("esas2r_read_fw: COMMAND length %d off %d",
length,
off);
if (off == 0) {
if (a->firmware.header.action == FI_ACT_UP) {
if (!allocate_fw_buffers(a, length))
return -ENOMEM;
/* copy header over */
memcpy(a->firmware.data,
&a->firmware.header,
sizeof(a->firmware.header));
do_fm_api(a,
(struct esas2r_flash_img *)a->firmware.data);
} else if (a->firmware.header.action == FI_ACT_UPSZ) {
int size =
min((int)count,
(int)sizeof(a->firmware.header));
do_fm_api(a, &a->firmware.header);
memcpy(buf, &a->firmware.header, size);
esas2r_debug("FI_ACT_UPSZ size %d", size);
return size;
} else {
esas2r_debug("invalid action %d",
a->firmware.header.action);
return -ENOSYS;
}
}
if (count + off > length)
count = length - off;
if (count < 0)
return 0;
if (!a->firmware.data) {
esas2r_debug(
"read: nonzero offset but no buffer available!");
return -ENOMEM;
}
esas2r_debug("esas2r_read_fw: off %d count %d length %d ", off,
count,
length);
memcpy(buf, &a->firmware.data[off], count);
/* when done, release the buffer */
if (length <= off + count) {
esas2r_debug("esas2r_read_fw: freeing buffer!");
free_fw_buffers(a);
}
return count;
}
esas2r_trace_exit();
esas2r_debug("esas2r_read_fw: invalid firmware state %d",
a->firmware.state);
return -EINVAL;
}
/* Handle a call to write firmware. */
int esas2r_write_fw(struct esas2r_adapter *a, const char *buf, long off,
int count)
{
u32 length;
if (off == 0) {
struct esas2r_flash_img *header =
(struct esas2r_flash_img *)buf;
/* assume version 0 flash image */
int min_size = sizeof(struct esas2r_flash_img_v0);
a->firmware.state = FW_INVALID_ST;
/* validate the version field first */
if (count < 4
|| header->fi_version > FI_VERSION_1) {
esas2r_debug(
"esas2r_write_fw: short header or invalid version");
return -EINVAL;
}
/* See if its a version 1 flash image */
if (header->fi_version == FI_VERSION_1)
min_size = sizeof(struct esas2r_flash_img);
/* If this is the start, the header must be full and valid. */
if (count < min_size) {
esas2r_debug("esas2r_write_fw: short header, aborting");
return -EINVAL;
}
/* Make sure the size is reasonable. */
length = header->length;
if (length > 1024 * 1024) {
esas2r_debug(
"esas2r_write_fw: hosed, length %d fi_version %d",
length, header->fi_version);
return -EINVAL;
}
/*
* If this is a write command, allocate memory because
* we have to cache everything. otherwise, just cache
* the header, because the read op will do the command.
*/
if (header->action == FI_ACT_DOWN) {
if (!allocate_fw_buffers(a, length))
return -ENOMEM;
/*
* Store the command, so there is context on subsequent
* calls.
*/
memcpy(&a->firmware.header,
buf,
sizeof(*header));
} else if (header->action == FI_ACT_UP
|| header->action == FI_ACT_UPSZ) {
/* Save the command, result will be picked up on read */
memcpy(&a->firmware.header,
buf,
sizeof(*header));
a->firmware.state = FW_COMMAND_ST;
esas2r_debug(
"esas2r_write_fw: COMMAND, count %d, action %d ",
count, header->action);
/*
* Pretend we took the whole buffer,
* so we don't get bothered again.
*/
return count;
} else {
esas2r_debug("esas2r_write_fw: invalid action %d ",
a->firmware.header.action);
return -ENOSYS;
}
} else {
length = a->firmware.header.length;
}
/*
* We only get here on a download command, regardless of offset.
* the chunks written by the system need to be cached, and when
* the final one arrives, issue the fmapi command.
*/
if (off + count > length)
count = length - off;
if (count > 0) {
esas2r_debug("esas2r_write_fw: off %d count %d length %d", off,
count,
length);
/*
* On a full upload, the system tries sending the whole buffer.
* there's nothing to do with it, so just drop it here, before
* trying to copy over into unallocated memory!
*/
if (a->firmware.header.action == FI_ACT_UP)
return count;
if (!a->firmware.data) {
esas2r_debug(
"write: nonzero offset but no buffer available!");
return -ENOMEM;
}
memcpy(&a->firmware.data[off], buf, count);
if (length == off + count) {
do_fm_api(a,
(struct esas2r_flash_img *)a->firmware.data);
/*
* Now copy the header result to be picked up by the
* next read
*/
memcpy(&a->firmware.header,
a->firmware.data,
sizeof(a->firmware.header));
a->firmware.state = FW_STATUS_ST;
esas2r_debug("write completed");
/*
* Since the system has the data buffered, the only way
* this can leak is if a root user writes a program
* that writes a shorter buffer than it claims, and the
* copyin fails.
*/
free_fw_buffers(a);
}
}
return count;
}
/* Callback for the completion of a VDA request. */
static void vda_complete_req(struct esas2r_adapter *a,
struct esas2r_request *rq)
{
a->vda_command_done = 1;
wake_up_interruptible(&a->vda_waiter);
}
/* Scatter/gather callback for VDA requests */
static u32 get_physaddr_vda(struct esas2r_sg_context *sgc, u64 *addr)
{
struct esas2r_adapter *a = (struct esas2r_adapter *)sgc->adapter;
int offset = (u8 *)sgc->cur_offset - (u8 *)a->vda_buffer;
(*addr) = a->ppvda_buffer + offset;
return VDA_MAX_BUFFER_SIZE - offset;
}
/* Handle a call to read a VDA command. */
int esas2r_read_vda(struct esas2r_adapter *a, char *buf, long off, int count)
{
if (!a->vda_buffer)
return -ENOMEM;
if (off == 0) {
struct esas2r_request *rq;
struct atto_ioctl_vda *vi =
(struct atto_ioctl_vda *)a->vda_buffer;
struct esas2r_sg_context sgc;
bool wait_for_completion;
/*
* Presumeably, someone has already written to the vda_buffer,
* and now they are reading the node the response, so now we
* will actually issue the request to the chip and reply.
*/
/* allocate a request */
rq = esas2r_alloc_request(a);
if (rq == NULL) {
esas2r_debug("esas2r_read_vda: out of requestss");
return -EBUSY;
}
rq->comp_cb = vda_complete_req;
sgc.first_req = rq;
sgc.adapter = a;
sgc.cur_offset = a->vda_buffer + VDA_BUFFER_HEADER_SZ;
sgc.get_phys_addr = (PGETPHYSADDR)get_physaddr_vda;
a->vda_command_done = 0;
wait_for_completion =
esas2r_process_vda_ioctl(a, vi, rq, &sgc);
if (wait_for_completion) {
/* now wait around for it to complete. */
while (!a->vda_command_done)
wait_event_interruptible(a->vda_waiter,
a->vda_command_done);
}
esas2r_free_request(a, (struct esas2r_request *)rq);
}
if (off > VDA_MAX_BUFFER_SIZE)
return 0;
if (count + off > VDA_MAX_BUFFER_SIZE)
count = VDA_MAX_BUFFER_SIZE - off;
if (count < 0)
return 0;
memcpy(buf, a->vda_buffer + off, count);
return count;
}
/* Handle a call to write a VDA command. */
int esas2r_write_vda(struct esas2r_adapter *a, const char *buf, long off,
int count)
{
/*
* allocate memory for it, if not already done. once allocated,
* we will keep it around until the driver is unloaded.
*/
if (!a->vda_buffer) {
dma_addr_t dma_addr;
a->vda_buffer = (u8 *)dma_alloc_coherent(&a->pcid->dev,
(size_t)
VDA_MAX_BUFFER_SIZE,
&dma_addr,
GFP_KERNEL);
a->ppvda_buffer = dma_addr;
}
if (!a->vda_buffer)
return -ENOMEM;
if (off > VDA_MAX_BUFFER_SIZE)
return 0;
if (count + off > VDA_MAX_BUFFER_SIZE)
count = VDA_MAX_BUFFER_SIZE - off;
if (count < 1)
return 0;
memcpy(a->vda_buffer + off, buf, count);
return count;
}
/* Callback for the completion of an FS_API request.*/
static void fs_api_complete_req(struct esas2r_adapter *a,
struct esas2r_request *rq)
{
a->fs_api_command_done = 1;
wake_up_interruptible(&a->fs_api_waiter);
}
/* Scatter/gather callback for VDA requests */
static u32 get_physaddr_fs_api(struct esas2r_sg_context *sgc, u64 *addr)
{
struct esas2r_adapter *a = (struct esas2r_adapter *)sgc->adapter;
struct esas2r_ioctl_fs *fs =
(struct esas2r_ioctl_fs *)a->fs_api_buffer;
u32 offset = (u8 *)sgc->cur_offset - (u8 *)fs;
(*addr) = a->ppfs_api_buffer + offset;
return a->fs_api_buffer_size - offset;
}
/* Handle a call to read firmware via FS_API. */
int esas2r_read_fs(struct esas2r_adapter *a, char *buf, long off, int count)
{
if (!a->fs_api_buffer)
return -ENOMEM;
if (off == 0) {
struct esas2r_request *rq;
struct esas2r_sg_context sgc;
struct esas2r_ioctl_fs *fs =
(struct esas2r_ioctl_fs *)a->fs_api_buffer;
/* If another flash request is already in progress, return. */
if (down_interruptible(&a->fs_api_semaphore)) {
busy:
fs->status = ATTO_STS_OUT_OF_RSRC;
return -EBUSY;
}
/*
* Presumeably, someone has already written to the
* fs_api_buffer, and now they are reading the node the
* response, so now we will actually issue the request to the
* chip and reply. Allocate a request
*/
rq = esas2r_alloc_request(a);
if (rq == NULL) {
esas2r_debug("esas2r_read_fs: out of requests");
up(&a->fs_api_semaphore);
goto busy;
}
rq->comp_cb = fs_api_complete_req;
/* Set up the SGCONTEXT for to build the s/g table */
sgc.cur_offset = fs->data;
sgc.get_phys_addr = (PGETPHYSADDR)get_physaddr_fs_api;
a->fs_api_command_done = 0;
if (!esas2r_process_fs_ioctl(a, fs, rq, &sgc)) {
if (fs->status == ATTO_STS_OUT_OF_RSRC)
count = -EBUSY;
goto dont_wait;
}
/* Now wait around for it to complete. */
while (!a->fs_api_command_done)
wait_event_interruptible(a->fs_api_waiter,
a->fs_api_command_done);
;
dont_wait:
/* Free the request and keep going */
up(&a->fs_api_semaphore);
esas2r_free_request(a, (struct esas2r_request *)rq);
/* Pick up possible error code from above */
if (count < 0)
return count;
}
if (off > a->fs_api_buffer_size)
return 0;
if (count + off > a->fs_api_buffer_size)
count = a->fs_api_buffer_size - off;
if (count < 0)
return 0;
memcpy(buf, a->fs_api_buffer + off, count);
return count;
}
/* Handle a call to write firmware via FS_API. */
int esas2r_write_fs(struct esas2r_adapter *a, const char *buf, long off,
int count)
{
if (off == 0) {
struct esas2r_ioctl_fs *fs = (struct esas2r_ioctl_fs *)buf;
u32 length = fs->command.length + offsetof(
struct esas2r_ioctl_fs,
data);
/*
* Special case, for BEGIN commands, the length field
* is lying to us, so just get enough for the header.
*/
if (fs->command.command == ESAS2R_FS_CMD_BEGINW)
length = offsetof(struct esas2r_ioctl_fs, data);
/*
* Beginning a command. We assume we'll get at least
* enough in the first write so we can look at the
* header and see how much we need to alloc.
*/
if (count < offsetof(struct esas2r_ioctl_fs, data))
return -EINVAL;
/* Allocate a buffer or use the existing buffer. */
if (a->fs_api_buffer) {
if (a->fs_api_buffer_size < length) {
/* Free too-small buffer and get a new one */
dma_free_coherent(&a->pcid->dev,
(size_t)a->fs_api_buffer_size,
a->fs_api_buffer,
(dma_addr_t)a->ppfs_api_buffer);
goto re_allocate_buffer;
}
} else {
re_allocate_buffer:
a->fs_api_buffer_size = length;
a->fs_api_buffer = (u8 *)dma_alloc_coherent(
&a->pcid->dev,
(size_t)a->fs_api_buffer_size,
(dma_addr_t *)&a->ppfs_api_buffer,
GFP_KERNEL);
}
}
if (!a->fs_api_buffer)
return -ENOMEM;
if (off > a->fs_api_buffer_size)
return 0;
if (count + off > a->fs_api_buffer_size)
count = a->fs_api_buffer_size - off;
if (count < 1)
return 0;
memcpy(a->fs_api_buffer + off, buf, count);
return count;
}