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/*
* ipr.c -- driver for IBM Power Linux RAID adapters
*
* Written By: Brian King <brking@us.ibm.com>, IBM Corporation
*
* Copyright (C) 2003, 2004 IBM Corporation
*
* 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.
*
* 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., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*
*/
/*
* Notes:
*
* This driver is used to control the following SCSI adapters:
*
* IBM iSeries: 5702, 5703, 2780, 5709, 570A, 570B
*
* IBM pSeries: PCI-X Dual Channel Ultra 320 SCSI RAID Adapter
* PCI-X Dual Channel Ultra 320 SCSI Adapter
* PCI-X Dual Channel Ultra 320 SCSI RAID Enablement Card
* Embedded SCSI adapter on p615 and p655 systems
*
* Supported Hardware Features:
* - Ultra 320 SCSI controller
* - PCI-X host interface
* - Embedded PowerPC RISC Processor and Hardware XOR DMA Engine
* - Non-Volatile Write Cache
* - Supports attachment of non-RAID disks, tape, and optical devices
* - RAID Levels 0, 5, 10
* - Hot spare
* - Background Parity Checking
* - Background Data Scrubbing
* - Ability to increase the capacity of an existing RAID 5 disk array
* by adding disks
*
* Driver Features:
* - Tagged command queuing
* - Adapter microcode download
* - PCI hot plug
* - SCSI device hot plug
*
*/
#include <linux/fs.h>
#include <linux/init.h>
#include <linux/types.h>
#include <linux/errno.h>
#include <linux/kernel.h>
#include <linux/slab.h>
#include <linux/vmalloc.h>
#include <linux/ioport.h>
#include <linux/delay.h>
#include <linux/pci.h>
#include <linux/wait.h>
#include <linux/spinlock.h>
#include <linux/sched.h>
#include <linux/interrupt.h>
#include <linux/blkdev.h>
#include <linux/firmware.h>
#include <linux/module.h>
#include <linux/moduleparam.h>
#include <linux/libata.h>
#include <linux/hdreg.h>
#include <linux/reboot.h>
#include <linux/stringify.h>
#include <asm/io.h>
#include <asm/irq.h>
#include <asm/processor.h>
#include <scsi/scsi.h>
#include <scsi/scsi_host.h>
#include <scsi/scsi_tcq.h>
#include <scsi/scsi_eh.h>
#include <scsi/scsi_cmnd.h>
#include "ipr.h"
/*
* Global Data
*/
static LIST_HEAD(ipr_ioa_head);
static unsigned int ipr_log_level = IPR_DEFAULT_LOG_LEVEL;
static unsigned int ipr_max_speed = 1;
static int ipr_testmode = 0;
static unsigned int ipr_fastfail = 0;
static unsigned int ipr_transop_timeout = 0;
static unsigned int ipr_debug = 0;
static unsigned int ipr_max_devs = IPR_DEFAULT_SIS64_DEVS;
static unsigned int ipr_dual_ioa_raid = 1;
static DEFINE_SPINLOCK(ipr_driver_lock);
/* This table describes the differences between DMA controller chips */
static const struct ipr_chip_cfg_t ipr_chip_cfg[] = {
{ /* Gemstone, Citrine, Obsidian, and Obsidian-E */
.mailbox = 0x0042C,
.cache_line_size = 0x20,
{
.set_interrupt_mask_reg = 0x0022C,
.clr_interrupt_mask_reg = 0x00230,
.clr_interrupt_mask_reg32 = 0x00230,
.sense_interrupt_mask_reg = 0x0022C,
.sense_interrupt_mask_reg32 = 0x0022C,
.clr_interrupt_reg = 0x00228,
.clr_interrupt_reg32 = 0x00228,
.sense_interrupt_reg = 0x00224,
.sense_interrupt_reg32 = 0x00224,
.ioarrin_reg = 0x00404,
.sense_uproc_interrupt_reg = 0x00214,
.sense_uproc_interrupt_reg32 = 0x00214,
.set_uproc_interrupt_reg = 0x00214,
.set_uproc_interrupt_reg32 = 0x00214,
.clr_uproc_interrupt_reg = 0x00218,
.clr_uproc_interrupt_reg32 = 0x00218
}
},
{ /* Snipe and Scamp */
.mailbox = 0x0052C,
.cache_line_size = 0x20,
{
.set_interrupt_mask_reg = 0x00288,
.clr_interrupt_mask_reg = 0x0028C,
.clr_interrupt_mask_reg32 = 0x0028C,
.sense_interrupt_mask_reg = 0x00288,
.sense_interrupt_mask_reg32 = 0x00288,
.clr_interrupt_reg = 0x00284,
.clr_interrupt_reg32 = 0x00284,
.sense_interrupt_reg = 0x00280,
.sense_interrupt_reg32 = 0x00280,
.ioarrin_reg = 0x00504,
.sense_uproc_interrupt_reg = 0x00290,
.sense_uproc_interrupt_reg32 = 0x00290,
.set_uproc_interrupt_reg = 0x00290,
.set_uproc_interrupt_reg32 = 0x00290,
.clr_uproc_interrupt_reg = 0x00294,
.clr_uproc_interrupt_reg32 = 0x00294
}
},
{ /* CRoC */
.mailbox = 0x00044,
.cache_line_size = 0x20,
{
.set_interrupt_mask_reg = 0x00010,
.clr_interrupt_mask_reg = 0x00018,
.clr_interrupt_mask_reg32 = 0x0001C,
.sense_interrupt_mask_reg = 0x00010,
.sense_interrupt_mask_reg32 = 0x00014,
.clr_interrupt_reg = 0x00008,
.clr_interrupt_reg32 = 0x0000C,
.sense_interrupt_reg = 0x00000,
.sense_interrupt_reg32 = 0x00004,
.ioarrin_reg = 0x00070,
.sense_uproc_interrupt_reg = 0x00020,
.sense_uproc_interrupt_reg32 = 0x00024,
.set_uproc_interrupt_reg = 0x00020,
.set_uproc_interrupt_reg32 = 0x00024,
.clr_uproc_interrupt_reg = 0x00028,
.clr_uproc_interrupt_reg32 = 0x0002C,
.init_feedback_reg = 0x0005C,
.dump_addr_reg = 0x00064,
.dump_data_reg = 0x00068,
.endian_swap_reg = 0x00084
}
},
};
static const struct ipr_chip_t ipr_chip[] = {
{ PCI_VENDOR_ID_MYLEX, PCI_DEVICE_ID_IBM_GEMSTONE, IPR_USE_LSI, IPR_SIS32, IPR_PCI_CFG, &ipr_chip_cfg[0] },
{ PCI_VENDOR_ID_IBM, PCI_DEVICE_ID_IBM_CITRINE, IPR_USE_LSI, IPR_SIS32, IPR_PCI_CFG, &ipr_chip_cfg[0] },
{ PCI_VENDOR_ID_ADAPTEC2, PCI_DEVICE_ID_ADAPTEC2_OBSIDIAN, IPR_USE_LSI, IPR_SIS32, IPR_PCI_CFG, &ipr_chip_cfg[0] },
{ PCI_VENDOR_ID_IBM, PCI_DEVICE_ID_IBM_OBSIDIAN, IPR_USE_LSI, IPR_SIS32, IPR_PCI_CFG, &ipr_chip_cfg[0] },
{ PCI_VENDOR_ID_IBM, PCI_DEVICE_ID_IBM_OBSIDIAN_E, IPR_USE_MSI, IPR_SIS32, IPR_PCI_CFG, &ipr_chip_cfg[0] },
{ PCI_VENDOR_ID_IBM, PCI_DEVICE_ID_IBM_SNIPE, IPR_USE_LSI, IPR_SIS32, IPR_PCI_CFG, &ipr_chip_cfg[1] },
{ PCI_VENDOR_ID_ADAPTEC2, PCI_DEVICE_ID_ADAPTEC2_SCAMP, IPR_USE_LSI, IPR_SIS32, IPR_PCI_CFG, &ipr_chip_cfg[1] },
{ PCI_VENDOR_ID_IBM, PCI_DEVICE_ID_IBM_CROC_FPGA_E2, IPR_USE_MSI, IPR_SIS64, IPR_MMIO, &ipr_chip_cfg[2] },
{ PCI_VENDOR_ID_IBM, PCI_DEVICE_ID_IBM_CROC_ASIC_E2, IPR_USE_MSI, IPR_SIS64, IPR_MMIO, &ipr_chip_cfg[2] }
};
static int ipr_max_bus_speeds [] = {
IPR_80MBs_SCSI_RATE, IPR_U160_SCSI_RATE, IPR_U320_SCSI_RATE
};
MODULE_AUTHOR("Brian King <brking@us.ibm.com>");
MODULE_DESCRIPTION("IBM Power RAID SCSI Adapter Driver");
module_param_named(max_speed, ipr_max_speed, uint, 0);
MODULE_PARM_DESC(max_speed, "Maximum bus speed (0-2). Default: 1=U160. Speeds: 0=80 MB/s, 1=U160, 2=U320");
module_param_named(log_level, ipr_log_level, uint, 0);
MODULE_PARM_DESC(log_level, "Set to 0 - 4 for increasing verbosity of device driver");
module_param_named(testmode, ipr_testmode, int, 0);
MODULE_PARM_DESC(testmode, "DANGEROUS!!! Allows unsupported configurations");
module_param_named(fastfail, ipr_fastfail, int, S_IRUGO | S_IWUSR);
MODULE_PARM_DESC(fastfail, "Reduce timeouts and retries");
module_param_named(transop_timeout, ipr_transop_timeout, int, 0);
MODULE_PARM_DESC(transop_timeout, "Time in seconds to wait for adapter to come operational (default: 300)");
module_param_named(debug, ipr_debug, int, S_IRUGO | S_IWUSR);
MODULE_PARM_DESC(debug, "Enable device driver debugging logging. Set to 1 to enable. (default: 0)");
module_param_named(dual_ioa_raid, ipr_dual_ioa_raid, int, 0);
MODULE_PARM_DESC(dual_ioa_raid, "Enable dual adapter RAID support. Set to 1 to enable. (default: 1)");
module_param_named(max_devs, ipr_max_devs, int, 0);
MODULE_PARM_DESC(max_devs, "Specify the maximum number of physical devices. "
"[Default=" __stringify(IPR_DEFAULT_SIS64_DEVS) "]");
MODULE_LICENSE("GPL");
MODULE_VERSION(IPR_DRIVER_VERSION);
/* A constant array of IOASCs/URCs/Error Messages */
static const
struct ipr_error_table_t ipr_error_table[] = {
{0x00000000, 1, IPR_DEFAULT_LOG_LEVEL,
"8155: An unknown error was received"},
{0x00330000, 0, 0,
"Soft underlength error"},
{0x005A0000, 0, 0,
"Command to be cancelled not found"},
{0x00808000, 0, 0,
"Qualified success"},
{0x01080000, 1, IPR_DEFAULT_LOG_LEVEL,
"FFFE: Soft device bus error recovered by the IOA"},
{0x01088100, 0, IPR_DEFAULT_LOG_LEVEL,
"4101: Soft device bus fabric error"},
{0x01100100, 0, IPR_DEFAULT_LOG_LEVEL,
"FFFC: Logical block guard error recovered by the device"},
{0x01100300, 0, IPR_DEFAULT_LOG_LEVEL,
"FFFC: Logical block reference tag error recovered by the device"},
{0x01108300, 0, IPR_DEFAULT_LOG_LEVEL,
"4171: Recovered scatter list tag / sequence number error"},
{0x01109000, 0, IPR_DEFAULT_LOG_LEVEL,
"FF3D: Recovered logical block CRC error on IOA to Host transfer"},
{0x01109200, 0, IPR_DEFAULT_LOG_LEVEL,
"4171: Recovered logical block sequence number error on IOA to Host transfer"},
{0x0110A000, 0, IPR_DEFAULT_LOG_LEVEL,
"FFFD: Recovered logical block reference tag error detected by the IOA"},
{0x0110A100, 0, IPR_DEFAULT_LOG_LEVEL,
"FFFD: Logical block guard error recovered by the IOA"},
{0x01170600, 0, IPR_DEFAULT_LOG_LEVEL,
"FFF9: Device sector reassign successful"},
{0x01170900, 0, IPR_DEFAULT_LOG_LEVEL,
"FFF7: Media error recovered by device rewrite procedures"},
{0x01180200, 0, IPR_DEFAULT_LOG_LEVEL,
"7001: IOA sector reassignment successful"},
{0x01180500, 0, IPR_DEFAULT_LOG_LEVEL,
"FFF9: Soft media error. Sector reassignment recommended"},
{0x01180600, 0, IPR_DEFAULT_LOG_LEVEL,
"FFF7: Media error recovered by IOA rewrite procedures"},
{0x01418000, 0, IPR_DEFAULT_LOG_LEVEL,
"FF3D: Soft PCI bus error recovered by the IOA"},
{0x01440000, 1, IPR_DEFAULT_LOG_LEVEL,
"FFF6: Device hardware error recovered by the IOA"},
{0x01448100, 0, IPR_DEFAULT_LOG_LEVEL,
"FFF6: Device hardware error recovered by the device"},
{0x01448200, 1, IPR_DEFAULT_LOG_LEVEL,
"FF3D: Soft IOA error recovered by the IOA"},
{0x01448300, 0, IPR_DEFAULT_LOG_LEVEL,
"FFFA: Undefined device response recovered by the IOA"},
{0x014A0000, 1, IPR_DEFAULT_LOG_LEVEL,
"FFF6: Device bus error, message or command phase"},
{0x014A8000, 0, IPR_DEFAULT_LOG_LEVEL,
"FFFE: Task Management Function failed"},
{0x015D0000, 0, IPR_DEFAULT_LOG_LEVEL,
"FFF6: Failure prediction threshold exceeded"},
{0x015D9200, 0, IPR_DEFAULT_LOG_LEVEL,
"8009: Impending cache battery pack failure"},
{0x02040400, 0, 0,
"34FF: Disk device format in progress"},
{0x02048000, 0, IPR_DEFAULT_LOG_LEVEL,
"9070: IOA requested reset"},
{0x023F0000, 0, 0,
"Synchronization required"},
{0x024E0000, 0, 0,
"No ready, IOA shutdown"},
{0x025A0000, 0, 0,
"Not ready, IOA has been shutdown"},
{0x02670100, 0, IPR_DEFAULT_LOG_LEVEL,
"3020: Storage subsystem configuration error"},
{0x03110B00, 0, 0,
"FFF5: Medium error, data unreadable, recommend reassign"},
{0x03110C00, 0, 0,
"7000: Medium error, data unreadable, do not reassign"},
{0x03310000, 0, IPR_DEFAULT_LOG_LEVEL,
"FFF3: Disk media format bad"},
{0x04050000, 0, IPR_DEFAULT_LOG_LEVEL,
"3002: Addressed device failed to respond to selection"},
{0x04080000, 1, IPR_DEFAULT_LOG_LEVEL,
"3100: Device bus error"},
{0x04080100, 0, IPR_DEFAULT_LOG_LEVEL,
"3109: IOA timed out a device command"},
{0x04088000, 0, 0,
"3120: SCSI bus is not operational"},
{0x04088100, 0, IPR_DEFAULT_LOG_LEVEL,
"4100: Hard device bus fabric error"},
{0x04100100, 0, IPR_DEFAULT_LOG_LEVEL,
"310C: Logical block guard error detected by the device"},
{0x04100300, 0, IPR_DEFAULT_LOG_LEVEL,
"310C: Logical block reference tag error detected by the device"},
{0x04108300, 1, IPR_DEFAULT_LOG_LEVEL,
"4170: Scatter list tag / sequence number error"},
{0x04109000, 1, IPR_DEFAULT_LOG_LEVEL,
"8150: Logical block CRC error on IOA to Host transfer"},
{0x04109200, 1, IPR_DEFAULT_LOG_LEVEL,
"4170: Logical block sequence number error on IOA to Host transfer"},
{0x0410A000, 0, IPR_DEFAULT_LOG_LEVEL,
"310D: Logical block reference tag error detected by the IOA"},
{0x0410A100, 0, IPR_DEFAULT_LOG_LEVEL,
"310D: Logical block guard error detected by the IOA"},
{0x04118000, 0, IPR_DEFAULT_LOG_LEVEL,
"9000: IOA reserved area data check"},
{0x04118100, 0, IPR_DEFAULT_LOG_LEVEL,
"9001: IOA reserved area invalid data pattern"},
{0x04118200, 0, IPR_DEFAULT_LOG_LEVEL,
"9002: IOA reserved area LRC error"},
{0x04118300, 1, IPR_DEFAULT_LOG_LEVEL,
"Hardware Error, IOA metadata access error"},
{0x04320000, 0, IPR_DEFAULT_LOG_LEVEL,
"102E: Out of alternate sectors for disk storage"},
{0x04330000, 1, IPR_DEFAULT_LOG_LEVEL,
"FFF4: Data transfer underlength error"},
{0x04338000, 1, IPR_DEFAULT_LOG_LEVEL,
"FFF4: Data transfer overlength error"},
{0x043E0100, 0, IPR_DEFAULT_LOG_LEVEL,
"3400: Logical unit failure"},
{0x04408500, 0, IPR_DEFAULT_LOG_LEVEL,
"FFF4: Device microcode is corrupt"},
{0x04418000, 1, IPR_DEFAULT_LOG_LEVEL,
"8150: PCI bus error"},
{0x04430000, 1, 0,
"Unsupported device bus message received"},
{0x04440000, 1, IPR_DEFAULT_LOG_LEVEL,
"FFF4: Disk device problem"},
{0x04448200, 1, IPR_DEFAULT_LOG_LEVEL,
"8150: Permanent IOA failure"},
{0x04448300, 0, IPR_DEFAULT_LOG_LEVEL,
"3010: Disk device returned wrong response to IOA"},
{0x04448400, 0, IPR_DEFAULT_LOG_LEVEL,
"8151: IOA microcode error"},
{0x04448500, 0, 0,
"Device bus status error"},
{0x04448600, 0, IPR_DEFAULT_LOG_LEVEL,
"8157: IOA error requiring IOA reset to recover"},
{0x04448700, 0, 0,
"ATA device status error"},
{0x04490000, 0, 0,
"Message reject received from the device"},
{0x04449200, 0, IPR_DEFAULT_LOG_LEVEL,
"8008: A permanent cache battery pack failure occurred"},
{0x0444A000, 0, IPR_DEFAULT_LOG_LEVEL,
"9090: Disk unit has been modified after the last known status"},
{0x0444A200, 0, IPR_DEFAULT_LOG_LEVEL,
"9081: IOA detected device error"},
{0x0444A300, 0, IPR_DEFAULT_LOG_LEVEL,
"9082: IOA detected device error"},
{0x044A0000, 1, IPR_DEFAULT_LOG_LEVEL,
"3110: Device bus error, message or command phase"},
{0x044A8000, 1, IPR_DEFAULT_LOG_LEVEL,
"3110: SAS Command / Task Management Function failed"},
{0x04670400, 0, IPR_DEFAULT_LOG_LEVEL,
"9091: Incorrect hardware configuration change has been detected"},
{0x04678000, 0, IPR_DEFAULT_LOG_LEVEL,
"9073: Invalid multi-adapter configuration"},
{0x04678100, 0, IPR_DEFAULT_LOG_LEVEL,
"4010: Incorrect connection between cascaded expanders"},
{0x04678200, 0, IPR_DEFAULT_LOG_LEVEL,
"4020: Connections exceed IOA design limits"},
{0x04678300, 0, IPR_DEFAULT_LOG_LEVEL,
"4030: Incorrect multipath connection"},
{0x04679000, 0, IPR_DEFAULT_LOG_LEVEL,
"4110: Unsupported enclosure function"},
{0x046E0000, 0, IPR_DEFAULT_LOG_LEVEL,
"FFF4: Command to logical unit failed"},
{0x05240000, 1, 0,
"Illegal request, invalid request type or request packet"},
{0x05250000, 0, 0,
"Illegal request, invalid resource handle"},
{0x05258000, 0, 0,
"Illegal request, commands not allowed to this device"},
{0x05258100, 0, 0,
"Illegal request, command not allowed to a secondary adapter"},
{0x05258200, 0, 0,
"Illegal request, command not allowed to a non-optimized resource"},
{0x05260000, 0, 0,
"Illegal request, invalid field in parameter list"},
{0x05260100, 0, 0,
"Illegal request, parameter not supported"},
{0x05260200, 0, 0,
"Illegal request, parameter value invalid"},
{0x052C0000, 0, 0,
"Illegal request, command sequence error"},
{0x052C8000, 1, 0,
"Illegal request, dual adapter support not enabled"},
{0x06040500, 0, IPR_DEFAULT_LOG_LEVEL,
"9031: Array protection temporarily suspended, protection resuming"},
{0x06040600, 0, IPR_DEFAULT_LOG_LEVEL,
"9040: Array protection temporarily suspended, protection resuming"},
{0x06288000, 0, IPR_DEFAULT_LOG_LEVEL,
"3140: Device bus not ready to ready transition"},
{0x06290000, 0, IPR_DEFAULT_LOG_LEVEL,
"FFFB: SCSI bus was reset"},
{0x06290500, 0, 0,
"FFFE: SCSI bus transition to single ended"},
{0x06290600, 0, 0,
"FFFE: SCSI bus transition to LVD"},
{0x06298000, 0, IPR_DEFAULT_LOG_LEVEL,
"FFFB: SCSI bus was reset by another initiator"},
{0x063F0300, 0, IPR_DEFAULT_LOG_LEVEL,
"3029: A device replacement has occurred"},
{0x064C8000, 0, IPR_DEFAULT_LOG_LEVEL,
"9051: IOA cache data exists for a missing or failed device"},
{0x064C8100, 0, IPR_DEFAULT_LOG_LEVEL,
"9055: Auxiliary cache IOA contains cache data needed by the primary IOA"},
{0x06670100, 0, IPR_DEFAULT_LOG_LEVEL,
"9025: Disk unit is not supported at its physical location"},
{0x06670600, 0, IPR_DEFAULT_LOG_LEVEL,
"3020: IOA detected a SCSI bus configuration error"},
{0x06678000, 0, IPR_DEFAULT_LOG_LEVEL,
"3150: SCSI bus configuration error"},
{0x06678100, 0, IPR_DEFAULT_LOG_LEVEL,
"9074: Asymmetric advanced function disk configuration"},
{0x06678300, 0, IPR_DEFAULT_LOG_LEVEL,
"4040: Incomplete multipath connection between IOA and enclosure"},
{0x06678400, 0, IPR_DEFAULT_LOG_LEVEL,
"4041: Incomplete multipath connection between enclosure and device"},
{0x06678500, 0, IPR_DEFAULT_LOG_LEVEL,
"9075: Incomplete multipath connection between IOA and remote IOA"},
{0x06678600, 0, IPR_DEFAULT_LOG_LEVEL,
"9076: Configuration error, missing remote IOA"},
{0x06679100, 0, IPR_DEFAULT_LOG_LEVEL,
"4050: Enclosure does not support a required multipath function"},
{0x06690000, 0, IPR_DEFAULT_LOG_LEVEL,
"4070: Logically bad block written on device"},
{0x06690200, 0, IPR_DEFAULT_LOG_LEVEL,
"9041: Array protection temporarily suspended"},
{0x06698200, 0, IPR_DEFAULT_LOG_LEVEL,
"9042: Corrupt array parity detected on specified device"},
{0x066B0200, 0, IPR_DEFAULT_LOG_LEVEL,
"9030: Array no longer protected due to missing or failed disk unit"},
{0x066B8000, 0, IPR_DEFAULT_LOG_LEVEL,
"9071: Link operational transition"},
{0x066B8100, 0, IPR_DEFAULT_LOG_LEVEL,
"9072: Link not operational transition"},
{0x066B8200, 0, IPR_DEFAULT_LOG_LEVEL,
"9032: Array exposed but still protected"},
{0x066B8300, 0, IPR_DEFAULT_LOG_LEVEL + 1,
"70DD: Device forced failed by disrupt device command"},
{0x066B9100, 0, IPR_DEFAULT_LOG_LEVEL,
"4061: Multipath redundancy level got better"},
{0x066B9200, 0, IPR_DEFAULT_LOG_LEVEL,
"4060: Multipath redundancy level got worse"},
{0x07270000, 0, 0,
"Failure due to other device"},
{0x07278000, 0, IPR_DEFAULT_LOG_LEVEL,
"9008: IOA does not support functions expected by devices"},
{0x07278100, 0, IPR_DEFAULT_LOG_LEVEL,
"9010: Cache data associated with attached devices cannot be found"},
{0x07278200, 0, IPR_DEFAULT_LOG_LEVEL,
"9011: Cache data belongs to devices other than those attached"},
{0x07278400, 0, IPR_DEFAULT_LOG_LEVEL,
"9020: Array missing 2 or more devices with only 1 device present"},
{0x07278500, 0, IPR_DEFAULT_LOG_LEVEL,
"9021: Array missing 2 or more devices with 2 or more devices present"},
{0x07278600, 0, IPR_DEFAULT_LOG_LEVEL,
"9022: Exposed array is missing a required device"},
{0x07278700, 0, IPR_DEFAULT_LOG_LEVEL,
"9023: Array member(s) not at required physical locations"},
{0x07278800, 0, IPR_DEFAULT_LOG_LEVEL,
"9024: Array not functional due to present hardware configuration"},
{0x07278900, 0, IPR_DEFAULT_LOG_LEVEL,
"9026: Array not functional due to present hardware configuration"},
{0x07278A00, 0, IPR_DEFAULT_LOG_LEVEL,
"9027: Array is missing a device and parity is out of sync"},
{0x07278B00, 0, IPR_DEFAULT_LOG_LEVEL,
"9028: Maximum number of arrays already exist"},
{0x07278C00, 0, IPR_DEFAULT_LOG_LEVEL,
"9050: Required cache data cannot be located for a disk unit"},
{0x07278D00, 0, IPR_DEFAULT_LOG_LEVEL,
"9052: Cache data exists for a device that has been modified"},
{0x07278F00, 0, IPR_DEFAULT_LOG_LEVEL,
"9054: IOA resources not available due to previous problems"},
{0x07279100, 0, IPR_DEFAULT_LOG_LEVEL,
"9092: Disk unit requires initialization before use"},
{0x07279200, 0, IPR_DEFAULT_LOG_LEVEL,
"9029: Incorrect hardware configuration change has been detected"},
{0x07279600, 0, IPR_DEFAULT_LOG_LEVEL,
"9060: One or more disk pairs are missing from an array"},
{0x07279700, 0, IPR_DEFAULT_LOG_LEVEL,
"9061: One or more disks are missing from an array"},
{0x07279800, 0, IPR_DEFAULT_LOG_LEVEL,
"9062: One or more disks are missing from an array"},
{0x07279900, 0, IPR_DEFAULT_LOG_LEVEL,
"9063: Maximum number of functional arrays has been exceeded"},
{0x0B260000, 0, 0,
"Aborted command, invalid descriptor"},
{0x0B5A0000, 0, 0,
"Command terminated by host"}
};
static const struct ipr_ses_table_entry ipr_ses_table[] = {
{ "2104-DL1 ", "XXXXXXXXXXXXXXXX", 80 },
{ "2104-TL1 ", "XXXXXXXXXXXXXXXX", 80 },
{ "HSBP07M P U2SCSI", "XXXXXXXXXXXXXXXX", 80 }, /* Hidive 7 slot */
{ "HSBP05M P U2SCSI", "XXXXXXXXXXXXXXXX", 80 }, /* Hidive 5 slot */
{ "HSBP05M S U2SCSI", "XXXXXXXXXXXXXXXX", 80 }, /* Bowtie */
{ "HSBP06E ASU2SCSI", "XXXXXXXXXXXXXXXX", 80 }, /* MartinFenning */
{ "2104-DU3 ", "XXXXXXXXXXXXXXXX", 160 },
{ "2104-TU3 ", "XXXXXXXXXXXXXXXX", 160 },
{ "HSBP04C RSU2SCSI", "XXXXXXX*XXXXXXXX", 160 },
{ "HSBP06E RSU2SCSI", "XXXXXXX*XXXXXXXX", 160 },
{ "St V1S2 ", "XXXXXXXXXXXXXXXX", 160 },
{ "HSBPD4M PU3SCSI", "XXXXXXX*XXXXXXXX", 160 },
{ "VSBPD1H U3SCSI", "XXXXXXX*XXXXXXXX", 160 }
};
/*
* Function Prototypes
*/
static int ipr_reset_alert(struct ipr_cmnd *);
static void ipr_process_ccn(struct ipr_cmnd *);
static void ipr_process_error(struct ipr_cmnd *);
static void ipr_reset_ioa_job(struct ipr_cmnd *);
static void ipr_initiate_ioa_reset(struct ipr_ioa_cfg *,
enum ipr_shutdown_type);
#ifdef CONFIG_SCSI_IPR_TRACE
/**
* ipr_trc_hook - Add a trace entry to the driver trace
* @ipr_cmd: ipr command struct
* @type: trace type
* @add_data: additional data
*
* Return value:
* none
**/
static void ipr_trc_hook(struct ipr_cmnd *ipr_cmd,
u8 type, u32 add_data)
{
struct ipr_trace_entry *trace_entry;
struct ipr_ioa_cfg *ioa_cfg = ipr_cmd->ioa_cfg;
trace_entry = &ioa_cfg->trace[ioa_cfg->trace_index++];
trace_entry->time = jiffies;
trace_entry->op_code = ipr_cmd->ioarcb.cmd_pkt.cdb[0];
trace_entry->type = type;
if (ipr_cmd->ioa_cfg->sis64)
trace_entry->ata_op_code = ipr_cmd->i.ata_ioadl.regs.command;
else
trace_entry->ata_op_code = ipr_cmd->ioarcb.u.add_data.u.regs.command;
trace_entry->cmd_index = ipr_cmd->cmd_index & 0xff;
trace_entry->res_handle = ipr_cmd->ioarcb.res_handle;
trace_entry->u.add_data = add_data;
}
#else
#define ipr_trc_hook(ipr_cmd, type, add_data) do { } while(0)
#endif
/**
* ipr_reinit_ipr_cmnd - Re-initialize an IPR Cmnd block for reuse
* @ipr_cmd: ipr command struct
*
* Return value:
* none
**/
static void ipr_reinit_ipr_cmnd(struct ipr_cmnd *ipr_cmd)
{
struct ipr_ioarcb *ioarcb = &ipr_cmd->ioarcb;
struct ipr_ioasa *ioasa = &ipr_cmd->s.ioasa;
struct ipr_ioasa64 *ioasa64 = &ipr_cmd->s.ioasa64;
dma_addr_t dma_addr = ipr_cmd->dma_addr;
memset(&ioarcb->cmd_pkt, 0, sizeof(struct ipr_cmd_pkt));
ioarcb->data_transfer_length = 0;
ioarcb->read_data_transfer_length = 0;
ioarcb->ioadl_len = 0;
ioarcb->read_ioadl_len = 0;
if (ipr_cmd->ioa_cfg->sis64) {
ioarcb->u.sis64_addr_data.data_ioadl_addr =
cpu_to_be64(dma_addr + offsetof(struct ipr_cmnd, i.ioadl64));
ioasa64->u.gata.status = 0;
} else {
ioarcb->write_ioadl_addr =
cpu_to_be32(dma_addr + offsetof(struct ipr_cmnd, i.ioadl));
ioarcb->read_ioadl_addr = ioarcb->write_ioadl_addr;
ioasa->u.gata.status = 0;
}
ioasa->hdr.ioasc = 0;
ioasa->hdr.residual_data_len = 0;
ipr_cmd->scsi_cmd = NULL;
ipr_cmd->qc = NULL;
ipr_cmd->sense_buffer[0] = 0;
ipr_cmd->dma_use_sg = 0;
}
/**
* ipr_init_ipr_cmnd - Initialize an IPR Cmnd block
* @ipr_cmd: ipr command struct
*
* Return value:
* none
**/
static void ipr_init_ipr_cmnd(struct ipr_cmnd *ipr_cmd)
{
ipr_reinit_ipr_cmnd(ipr_cmd);
ipr_cmd->u.scratch = 0;
ipr_cmd->sibling = NULL;
init_timer(&ipr_cmd->timer);
}
/**
* ipr_get_free_ipr_cmnd - Get a free IPR Cmnd block
* @ioa_cfg: ioa config struct
*
* Return value:
* pointer to ipr command struct
**/
static
struct ipr_cmnd *ipr_get_free_ipr_cmnd(struct ipr_ioa_cfg *ioa_cfg)
{
struct ipr_cmnd *ipr_cmd;
ipr_cmd = list_entry(ioa_cfg->free_q.next, struct ipr_cmnd, queue);
list_del(&ipr_cmd->queue);
ipr_init_ipr_cmnd(ipr_cmd);
return ipr_cmd;
}
/**
* ipr_mask_and_clear_interrupts - Mask all and clear specified interrupts
* @ioa_cfg: ioa config struct
* @clr_ints: interrupts to clear
*
* This function masks all interrupts on the adapter, then clears the
* interrupts specified in the mask
*
* Return value:
* none
**/
static void ipr_mask_and_clear_interrupts(struct ipr_ioa_cfg *ioa_cfg,
u32 clr_ints)
{
volatile u32 int_reg;
/* Stop new interrupts */
ioa_cfg->allow_interrupts = 0;
/* Set interrupt mask to stop all new interrupts */
if (ioa_cfg->sis64)
writeq(~0, ioa_cfg->regs.set_interrupt_mask_reg);
else
writel(~0, ioa_cfg->regs.set_interrupt_mask_reg);
/* Clear any pending interrupts */
if (ioa_cfg->sis64)
writel(~0, ioa_cfg->regs.clr_interrupt_reg);
writel(clr_ints, ioa_cfg->regs.clr_interrupt_reg32);
int_reg = readl(ioa_cfg->regs.sense_interrupt_reg);
}
/**
* ipr_save_pcix_cmd_reg - Save PCI-X command register
* @ioa_cfg: ioa config struct
*
* Return value:
* 0 on success / -EIO on failure
**/
static int ipr_save_pcix_cmd_reg(struct ipr_ioa_cfg *ioa_cfg)
{
int pcix_cmd_reg = pci_find_capability(ioa_cfg->pdev, PCI_CAP_ID_PCIX);
if (pcix_cmd_reg == 0)
return 0;
if (pci_read_config_word(ioa_cfg->pdev, pcix_cmd_reg + PCI_X_CMD,
&ioa_cfg->saved_pcix_cmd_reg) != PCIBIOS_SUCCESSFUL) {
dev_err(&ioa_cfg->pdev->dev, "Failed to save PCI-X command register\n");
return -EIO;
}
ioa_cfg->saved_pcix_cmd_reg |= PCI_X_CMD_DPERR_E | PCI_X_CMD_ERO;
return 0;
}
/**
* ipr_set_pcix_cmd_reg - Setup PCI-X command register
* @ioa_cfg: ioa config struct
*
* Return value:
* 0 on success / -EIO on failure
**/
static int ipr_set_pcix_cmd_reg(struct ipr_ioa_cfg *ioa_cfg)
{
int pcix_cmd_reg = pci_find_capability(ioa_cfg->pdev, PCI_CAP_ID_PCIX);
if (pcix_cmd_reg) {
if (pci_write_config_word(ioa_cfg->pdev, pcix_cmd_reg + PCI_X_CMD,
ioa_cfg->saved_pcix_cmd_reg) != PCIBIOS_SUCCESSFUL) {
dev_err(&ioa_cfg->pdev->dev, "Failed to setup PCI-X command register\n");
return -EIO;
}
}
return 0;
}
/**
* ipr_sata_eh_done - done function for aborted SATA commands
* @ipr_cmd: ipr command struct
*
* This function is invoked for ops generated to SATA
* devices which are being aborted.
*
* Return value:
* none
**/
static void ipr_sata_eh_done(struct ipr_cmnd *ipr_cmd)
{
struct ipr_ioa_cfg *ioa_cfg = ipr_cmd->ioa_cfg;
struct ata_queued_cmd *qc = ipr_cmd->qc;
struct ipr_sata_port *sata_port = qc->ap->private_data;
qc->err_mask |= AC_ERR_OTHER;
sata_port->ioasa.status |= ATA_BUSY;
list_add_tail(&ipr_cmd->queue, &ioa_cfg->free_q);
ata_qc_complete(qc);
}
/**
* ipr_scsi_eh_done - mid-layer done function for aborted ops
* @ipr_cmd: ipr command struct
*
* This function is invoked by the interrupt handler for
* ops generated by the SCSI mid-layer which are being aborted.
*
* Return value:
* none
**/
static void ipr_scsi_eh_done(struct ipr_cmnd *ipr_cmd)
{
struct ipr_ioa_cfg *ioa_cfg = ipr_cmd->ioa_cfg;
struct scsi_cmnd *scsi_cmd = ipr_cmd->scsi_cmd;
scsi_cmd->result |= (DID_ERROR << 16);
scsi_dma_unmap(ipr_cmd->scsi_cmd);
scsi_cmd->scsi_done(scsi_cmd);
list_add_tail(&ipr_cmd->queue, &ioa_cfg->free_q);
}
/**
* ipr_fail_all_ops - Fails all outstanding ops.
* @ioa_cfg: ioa config struct
*
* This function fails all outstanding ops.
*
* Return value:
* none
**/
static void ipr_fail_all_ops(struct ipr_ioa_cfg *ioa_cfg)
{
struct ipr_cmnd *ipr_cmd, *temp;
ENTER;
list_for_each_entry_safe(ipr_cmd, temp, &ioa_cfg->pending_q, queue) {
list_del(&ipr_cmd->queue);
ipr_cmd->s.ioasa.hdr.ioasc = cpu_to_be32(IPR_IOASC_IOA_WAS_RESET);
ipr_cmd->s.ioasa.hdr.ilid = cpu_to_be32(IPR_DRIVER_ILID);
if (ipr_cmd->scsi_cmd)
ipr_cmd->done = ipr_scsi_eh_done;
else if (ipr_cmd->qc)
ipr_cmd->done = ipr_sata_eh_done;
ipr_trc_hook(ipr_cmd, IPR_TRACE_FINISH, IPR_IOASC_IOA_WAS_RESET);
del_timer(&ipr_cmd->timer);
ipr_cmd->done(ipr_cmd);
}
LEAVE;
}
/**
* ipr_send_command - Send driver initiated requests.
* @ipr_cmd: ipr command struct
*
* This function sends a command to the adapter using the correct write call.
* In the case of sis64, calculate the ioarcb size required. Then or in the
* appropriate bits.
*
* Return value:
* none
**/
static void ipr_send_command(struct ipr_cmnd *ipr_cmd)
{
struct ipr_ioa_cfg *ioa_cfg = ipr_cmd->ioa_cfg;
dma_addr_t send_dma_addr = ipr_cmd->dma_addr;
if (ioa_cfg->sis64) {
/* The default size is 256 bytes */
send_dma_addr |= 0x1;
/* If the number of ioadls * size of ioadl > 128 bytes,
then use a 512 byte ioarcb */
if (ipr_cmd->dma_use_sg * sizeof(struct ipr_ioadl64_desc) > 128 )
send_dma_addr |= 0x4;
writeq(send_dma_addr, ioa_cfg->regs.ioarrin_reg);
} else
writel(send_dma_addr, ioa_cfg->regs.ioarrin_reg);
}
/**
* ipr_do_req - Send driver initiated requests.
* @ipr_cmd: ipr command struct
* @done: done function
* @timeout_func: timeout function
* @timeout: timeout value
*
* This function sends the specified command to the adapter with the
* timeout given. The done function is invoked on command completion.
*
* Return value:
* none
**/
static void ipr_do_req(struct ipr_cmnd *ipr_cmd,
void (*done) (struct ipr_cmnd *),
void (*timeout_func) (struct ipr_cmnd *), u32 timeout)
{
struct ipr_ioa_cfg *ioa_cfg = ipr_cmd->ioa_cfg;
list_add_tail(&ipr_cmd->queue, &ioa_cfg->pending_q);
ipr_cmd->done = done;
ipr_cmd->timer.data = (unsigned long) ipr_cmd;
ipr_cmd->timer.expires = jiffies + timeout;
ipr_cmd->timer.function = (void (*)(unsigned long))timeout_func;
add_timer(&ipr_cmd->timer);
ipr_trc_hook(ipr_cmd, IPR_TRACE_START, 0);
mb();
ipr_send_command(ipr_cmd);
}
/**
* ipr_internal_cmd_done - Op done function for an internally generated op.
* @ipr_cmd: ipr command struct
*
* This function is the op done function for an internally generated,
* blocking op. It simply wakes the sleeping thread.
*
* Return value:
* none
**/
static void ipr_internal_cmd_done(struct ipr_cmnd *ipr_cmd)
{
if (ipr_cmd->sibling)
ipr_cmd->sibling = NULL;
else
complete(&ipr_cmd->completion);
}
/**
* ipr_init_ioadl - initialize the ioadl for the correct SIS type
* @ipr_cmd: ipr command struct
* @dma_addr: dma address
* @len: transfer length
* @flags: ioadl flag value
*
* This function initializes an ioadl in the case where there is only a single
* descriptor.
*
* Return value:
* nothing
**/
static void ipr_init_ioadl(struct ipr_cmnd *ipr_cmd, dma_addr_t dma_addr,
u32 len, int flags)
{
struct ipr_ioadl_desc *ioadl = ipr_cmd->i.ioadl;
struct ipr_ioadl64_desc *ioadl64 = ipr_cmd->i.ioadl64;
ipr_cmd->dma_use_sg = 1;
if (ipr_cmd->ioa_cfg->sis64) {
ioadl64->flags = cpu_to_be32(flags);
ioadl64->data_len = cpu_to_be32(len);
ioadl64->address = cpu_to_be64(dma_addr);
ipr_cmd->ioarcb.ioadl_len =
cpu_to_be32(sizeof(struct ipr_ioadl64_desc));
ipr_cmd->ioarcb.data_transfer_length = cpu_to_be32(len);
} else {
ioadl->flags_and_data_len = cpu_to_be32(flags | len);
ioadl->address = cpu_to_be32(dma_addr);
if (flags == IPR_IOADL_FLAGS_READ_LAST) {
ipr_cmd->ioarcb.read_ioadl_len =
cpu_to_be32(sizeof(struct ipr_ioadl_desc));
ipr_cmd->ioarcb.read_data_transfer_length = cpu_to_be32(len);
} else {
ipr_cmd->ioarcb.ioadl_len =
cpu_to_be32(sizeof(struct ipr_ioadl_desc));
ipr_cmd->ioarcb.data_transfer_length = cpu_to_be32(len);
}
}
}
/**
* ipr_send_blocking_cmd - Send command and sleep on its completion.
* @ipr_cmd: ipr command struct
* @timeout_func: function to invoke if command times out
* @timeout: timeout
*
* Return value:
* none
**/
static void ipr_send_blocking_cmd(struct ipr_cmnd *ipr_cmd,
void (*timeout_func) (struct ipr_cmnd *ipr_cmd),
u32 timeout)
{
struct ipr_ioa_cfg *ioa_cfg = ipr_cmd->ioa_cfg;
init_completion(&ipr_cmd->completion);
ipr_do_req(ipr_cmd, ipr_internal_cmd_done, timeout_func, timeout);
spin_unlock_irq(ioa_cfg->host->host_lock);
wait_for_completion(&ipr_cmd->completion);
spin_lock_irq(ioa_cfg->host->host_lock);
}
/**
* ipr_send_hcam - Send an HCAM to the adapter.
* @ioa_cfg: ioa config struct
* @type: HCAM type
* @hostrcb: hostrcb struct
*
* This function will send a Host Controlled Async command to the adapter.
* If HCAMs are currently not allowed to be issued to the adapter, it will
* place the hostrcb on the free queue.
*
* Return value:
* none
**/
static void ipr_send_hcam(struct ipr_ioa_cfg *ioa_cfg, u8 type,
struct ipr_hostrcb *hostrcb)
{
struct ipr_cmnd *ipr_cmd;
struct ipr_ioarcb *ioarcb;
if (ioa_cfg->allow_cmds) {
ipr_cmd = ipr_get_free_ipr_cmnd(ioa_cfg);
list_add_tail(&ipr_cmd->queue, &ioa_cfg->pending_q);
list_add_tail(&hostrcb->queue, &ioa_cfg->hostrcb_pending_q);
ipr_cmd->u.hostrcb = hostrcb;
ioarcb = &ipr_cmd->ioarcb;
ioarcb->res_handle = cpu_to_be32(IPR_IOA_RES_HANDLE);
ioarcb->cmd_pkt.request_type = IPR_RQTYPE_HCAM;
ioarcb->cmd_pkt.cdb[0] = IPR_HOST_CONTROLLED_ASYNC;
ioarcb->cmd_pkt.cdb[1] = type;
ioarcb->cmd_pkt.cdb[7] = (sizeof(hostrcb->hcam) >> 8) & 0xff;
ioarcb->cmd_pkt.cdb[8] = sizeof(hostrcb->hcam) & 0xff;
ipr_init_ioadl(ipr_cmd, hostrcb->hostrcb_dma,
sizeof(hostrcb->hcam), IPR_IOADL_FLAGS_READ_LAST);
if (type == IPR_HCAM_CDB_OP_CODE_CONFIG_CHANGE)
ipr_cmd->done = ipr_process_ccn;
else
ipr_cmd->done = ipr_process_error;
ipr_trc_hook(ipr_cmd, IPR_TRACE_START, IPR_IOA_RES_ADDR);
mb();
ipr_send_command(ipr_cmd);
} else {
list_add_tail(&hostrcb->queue, &ioa_cfg->hostrcb_free_q);
}
}
/**
* ipr_update_ata_class - Update the ata class in the resource entry
* @res: resource entry struct
* @proto: cfgte device bus protocol value
*
* Return value:
* none
**/
static void ipr_update_ata_class(struct ipr_resource_entry *res, unsigned int proto)
{
switch(proto) {
case IPR_PROTO_SATA:
case IPR_PROTO_SAS_STP:
res->ata_class = ATA_DEV_ATA;
break;
case IPR_PROTO_SATA_ATAPI:
case IPR_PROTO_SAS_STP_ATAPI:
res->ata_class = ATA_DEV_ATAPI;
break;
default:
res->ata_class = ATA_DEV_UNKNOWN;
break;
};
}
/**
* ipr_init_res_entry - Initialize a resource entry struct.
* @res: resource entry struct
* @cfgtew: config table entry wrapper struct
*
* Return value:
* none
**/
static void ipr_init_res_entry(struct ipr_resource_entry *res,
struct ipr_config_table_entry_wrapper *cfgtew)
{
int found = 0;
unsigned int proto;
struct ipr_ioa_cfg *ioa_cfg = res->ioa_cfg;
struct ipr_resource_entry *gscsi_res = NULL;
res->needs_sync_complete = 0;
res->in_erp = 0;
res->add_to_ml = 0;
res->del_from_ml = 0;
res->resetting_device = 0;
res->sdev = NULL;
res->sata_port = NULL;
if (ioa_cfg->sis64) {
proto = cfgtew->u.cfgte64->proto;
res->res_flags = cfgtew->u.cfgte64->res_flags;
res->qmodel = IPR_QUEUEING_MODEL64(res);
res->type = cfgtew->u.cfgte64->res_type;
memcpy(res->res_path, &cfgtew->u.cfgte64->res_path,
sizeof(res->res_path));
res->bus = 0;
memcpy(&res->dev_lun.scsi_lun, &cfgtew->u.cfgte64->lun,
sizeof(res->dev_lun.scsi_lun));
res->lun = scsilun_to_int(&res->dev_lun);
if (res->type == IPR_RES_TYPE_GENERIC_SCSI) {
list_for_each_entry(gscsi_res, &ioa_cfg->used_res_q, queue) {
if (gscsi_res->dev_id == cfgtew->u.cfgte64->dev_id) {
found = 1;
res->target = gscsi_res->target;
break;
}
}
if (!found) {
res->target = find_first_zero_bit(ioa_cfg->target_ids,
ioa_cfg->max_devs_supported);
set_bit(res->target, ioa_cfg->target_ids);
}
} else if (res->type == IPR_RES_TYPE_IOAFP) {
res->bus = IPR_IOAFP_VIRTUAL_BUS;
res->target = 0;
} else if (res->type == IPR_RES_TYPE_ARRAY) {
res->bus = IPR_ARRAY_VIRTUAL_BUS;
res->target = find_first_zero_bit(ioa_cfg->array_ids,
ioa_cfg->max_devs_supported);
set_bit(res->target, ioa_cfg->array_ids);
} else if (res->type == IPR_RES_TYPE_VOLUME_SET) {
res->bus = IPR_VSET_VIRTUAL_BUS;
res->target = find_first_zero_bit(ioa_cfg->vset_ids,
ioa_cfg->max_devs_supported);
set_bit(res->target, ioa_cfg->vset_ids);
} else {
res->target = find_first_zero_bit(ioa_cfg->target_ids,
ioa_cfg->max_devs_supported);
set_bit(res->target, ioa_cfg->target_ids);
}
} else {
proto = cfgtew->u.cfgte->proto;
res->qmodel = IPR_QUEUEING_MODEL(res);
res->flags = cfgtew->u.cfgte->flags;
if (res->flags & IPR_IS_IOA_RESOURCE)
res->type = IPR_RES_TYPE_IOAFP;
else
res->type = cfgtew->u.cfgte->rsvd_subtype & 0x0f;
res->bus = cfgtew->u.cfgte->res_addr.bus;
res->target = cfgtew->u.cfgte->res_addr.target;
res->lun = cfgtew->u.cfgte->res_addr.lun;
res->lun_wwn = get_unaligned_be64(cfgtew->u.cfgte->lun_wwn);
}
ipr_update_ata_class(res, proto);
}
/**
* ipr_is_same_device - Determine if two devices are the same.
* @res: resource entry struct
* @cfgtew: config table entry wrapper struct
*
* Return value:
* 1 if the devices are the same / 0 otherwise
**/
static int ipr_is_same_device(struct ipr_resource_entry *res,
struct ipr_config_table_entry_wrapper *cfgtew)
{
if (res->ioa_cfg->sis64) {
if (!memcmp(&res->dev_id, &cfgtew->u.cfgte64->dev_id,
sizeof(cfgtew->u.cfgte64->dev_id)) &&
!memcmp(&res->dev_lun.scsi_lun, &cfgtew->u.cfgte64->lun,
sizeof(cfgtew->u.cfgte64->lun))) {
return 1;
}
} else {
if (res->bus == cfgtew->u.cfgte->res_addr.bus &&
res->target == cfgtew->u.cfgte->res_addr.target &&
res->lun == cfgtew->u.cfgte->res_addr.lun)
return 1;
}
return 0;
}
/**
* ipr_format_res_path - Format the resource path for printing.
* @res_path: resource path
* @buf: buffer
*
* Return value:
* pointer to buffer
**/
static char *ipr_format_res_path(u8 *res_path, char *buffer, int len)
{
int i;
char *p = buffer;
*p = '\0';
p += snprintf(p, buffer + len - p, "%02X", res_path[0]);
for (i = 1; res_path[i] != 0xff && ((i * 3) < len); i++)
p += snprintf(p, buffer + len - p, "-%02X", res_path[i]);
return buffer;
}
/**
* ipr_update_res_entry - Update the resource entry.
* @res: resource entry struct
* @cfgtew: config table entry wrapper struct
*
* Return value:
* none
**/
static void ipr_update_res_entry(struct ipr_resource_entry *res,
struct ipr_config_table_entry_wrapper *cfgtew)
{
char buffer[IPR_MAX_RES_PATH_LENGTH];
unsigned int proto;
int new_path = 0;
if (res->ioa_cfg->sis64) {
res->flags = cfgtew->u.cfgte64->flags;
res->res_flags = cfgtew->u.cfgte64->res_flags;
res->type = cfgtew->u.cfgte64->res_type;
memcpy(&res->std_inq_data, &cfgtew->u.cfgte64->std_inq_data,
sizeof(struct ipr_std_inq_data));
res->qmodel = IPR_QUEUEING_MODEL64(res);
proto = cfgtew->u.cfgte64->proto;
res->res_handle = cfgtew->u.cfgte64->res_handle;
res->dev_id = cfgtew->u.cfgte64->dev_id;
memcpy(&res->dev_lun.scsi_lun, &cfgtew->u.cfgte64->lun,
sizeof(res->dev_lun.scsi_lun));
if (memcmp(res->res_path, &cfgtew->u.cfgte64->res_path,
sizeof(res->res_path))) {
memcpy(res->res_path, &cfgtew->u.cfgte64->res_path,
sizeof(res->res_path));
new_path = 1;
}
if (res->sdev && new_path)
sdev_printk(KERN_INFO, res->sdev, "Resource path: %s\n",
ipr_format_res_path(res->res_path, buffer,
sizeof(buffer)));
} else {
res->flags = cfgtew->u.cfgte->flags;
if (res->flags & IPR_IS_IOA_RESOURCE)
res->type = IPR_RES_TYPE_IOAFP;
else
res->type = cfgtew->u.cfgte->rsvd_subtype & 0x0f;
memcpy(&res->std_inq_data, &cfgtew->u.cfgte->std_inq_data,
sizeof(struct ipr_std_inq_data));
res->qmodel = IPR_QUEUEING_MODEL(res);
proto = cfgtew->u.cfgte->proto;
res->res_handle = cfgtew->u.cfgte->res_handle;
}
ipr_update_ata_class(res, proto);
}
/**
* ipr_clear_res_target - Clear the bit in the bit map representing the target
* for the resource.
* @res: resource entry struct
* @cfgtew: config table entry wrapper struct
*
* Return value:
* none
**/
static void ipr_clear_res_target(struct ipr_resource_entry *res)
{
struct ipr_resource_entry *gscsi_res = NULL;
struct ipr_ioa_cfg *ioa_cfg = res->ioa_cfg;
if (!ioa_cfg->sis64)
return;
if (res->bus == IPR_ARRAY_VIRTUAL_BUS)
clear_bit(res->target, ioa_cfg->array_ids);
else if (res->bus == IPR_VSET_VIRTUAL_BUS)
clear_bit(res->target, ioa_cfg->vset_ids);
else if (res->bus == 0 && res->type == IPR_RES_TYPE_GENERIC_SCSI) {
list_for_each_entry(gscsi_res, &ioa_cfg->used_res_q, queue)
if (gscsi_res->dev_id == res->dev_id && gscsi_res != res)
return;
clear_bit(res->target, ioa_cfg->target_ids);
} else if (res->bus == 0)
clear_bit(res->target, ioa_cfg->target_ids);
}
/**
* ipr_handle_config_change - Handle a config change from the adapter
* @ioa_cfg: ioa config struct
* @hostrcb: hostrcb
*
* Return value:
* none
**/
static void ipr_handle_config_change(struct ipr_ioa_cfg *ioa_cfg,
struct ipr_hostrcb *hostrcb)
{
struct ipr_resource_entry *res = NULL;
struct ipr_config_table_entry_wrapper cfgtew;
__be32 cc_res_handle;
u32 is_ndn = 1;
if (ioa_cfg->sis64) {
cfgtew.u.cfgte64 = &hostrcb->hcam.u.ccn.u.cfgte64;
cc_res_handle = cfgtew.u.cfgte64->res_handle;
} else {
cfgtew.u.cfgte = &hostrcb->hcam.u.ccn.u.cfgte;
cc_res_handle = cfgtew.u.cfgte->res_handle;
}
list_for_each_entry(res, &ioa_cfg->used_res_q, queue) {
if (res->res_handle == cc_res_handle) {
is_ndn = 0;
break;
}
}
if (is_ndn) {
if (list_empty(&ioa_cfg->free_res_q)) {
ipr_send_hcam(ioa_cfg,
IPR_HCAM_CDB_OP_CODE_CONFIG_CHANGE,
hostrcb);
return;
}
res = list_entry(ioa_cfg->free_res_q.next,
struct ipr_resource_entry, queue);
list_del(&res->queue);
ipr_init_res_entry(res, &cfgtew);
list_add_tail(&res->queue, &ioa_cfg->used_res_q);
}
ipr_update_res_entry(res, &cfgtew);
if (hostrcb->hcam.notify_type == IPR_HOST_RCB_NOTIF_TYPE_REM_ENTRY) {
if (res->sdev) {
res->del_from_ml = 1;
res->res_handle = IPR_INVALID_RES_HANDLE;
if (ioa_cfg->allow_ml_add_del)
schedule_work(&ioa_cfg->work_q);
} else {
ipr_clear_res_target(res);
list_move_tail(&res->queue, &ioa_cfg->free_res_q);
}
} else if (!res->sdev || res->del_from_ml) {
res->add_to_ml = 1;
if (ioa_cfg->allow_ml_add_del)
schedule_work(&ioa_cfg->work_q);
}
ipr_send_hcam(ioa_cfg, IPR_HCAM_CDB_OP_CODE_CONFIG_CHANGE, hostrcb);
}
/**
* ipr_process_ccn - Op done function for a CCN.
* @ipr_cmd: ipr command struct
*
* This function is the op done function for a configuration
* change notification host controlled async from the adapter.
*
* Return value:
* none
**/
static void ipr_process_ccn(struct ipr_cmnd *ipr_cmd)
{
struct ipr_ioa_cfg *ioa_cfg = ipr_cmd->ioa_cfg;
struct ipr_hostrcb *hostrcb = ipr_cmd->u.hostrcb;
u32 ioasc = be32_to_cpu(ipr_cmd->s.ioasa.hdr.ioasc);
list_del(&hostrcb->queue);
list_add_tail(&ipr_cmd->queue, &ioa_cfg->free_q);
if (ioasc) {
if (ioasc != IPR_IOASC_IOA_WAS_RESET)
dev_err(&ioa_cfg->pdev->dev,
"Host RCB failed with IOASC: 0x%08X\n", ioasc);
ipr_send_hcam(ioa_cfg, IPR_HCAM_CDB_OP_CODE_CONFIG_CHANGE, hostrcb);
} else {
ipr_handle_config_change(ioa_cfg, hostrcb);
}
}
/**
* strip_and_pad_whitespace - Strip and pad trailing whitespace.
* @i: index into buffer
* @buf: string to modify
*
* This function will strip all trailing whitespace, pad the end
* of the string with a single space, and NULL terminate the string.
*
* Return value:
* new length of string
**/
static int strip_and_pad_whitespace(int i, char *buf)
{
while (i && buf[i] == ' ')
i--;
buf[i+1] = ' ';
buf[i+2] = '\0';
return i + 2;
}
/**
* ipr_log_vpd_compact - Log the passed extended VPD compactly.
* @prefix: string to print at start of printk
* @hostrcb: hostrcb pointer
* @vpd: vendor/product id/sn struct
*
* Return value:
* none
**/
static void ipr_log_vpd_compact(char *prefix, struct ipr_hostrcb *hostrcb,
struct ipr_vpd *vpd)
{
char buffer[IPR_VENDOR_ID_LEN + IPR_PROD_ID_LEN + IPR_SERIAL_NUM_LEN + 3];
int i = 0;
memcpy(buffer, vpd->vpids.vendor_id, IPR_VENDOR_ID_LEN);
i = strip_and_pad_whitespace(IPR_VENDOR_ID_LEN - 1, buffer);
memcpy(&buffer[i], vpd->vpids.product_id, IPR_PROD_ID_LEN);
i = strip_and_pad_whitespace(i + IPR_PROD_ID_LEN - 1, buffer);
memcpy(&buffer[i], vpd->sn, IPR_SERIAL_NUM_LEN);
buffer[IPR_SERIAL_NUM_LEN + i] = '\0';
ipr_hcam_err(hostrcb, "%s VPID/SN: %s\n", prefix, buffer);
}
/**
* ipr_log_vpd - Log the passed VPD to the error log.
* @vpd: vendor/product id/sn struct
*
* Return value:
* none
**/
static void ipr_log_vpd(struct ipr_vpd *vpd)
{
char buffer[IPR_VENDOR_ID_LEN + IPR_PROD_ID_LEN
+ IPR_SERIAL_NUM_LEN];
memcpy(buffer, vpd->vpids.vendor_id, IPR_VENDOR_ID_LEN);
memcpy(buffer + IPR_VENDOR_ID_LEN, vpd->vpids.product_id,
IPR_PROD_ID_LEN);
buffer[IPR_VENDOR_ID_LEN + IPR_PROD_ID_LEN] = '\0';
ipr_err("Vendor/Product ID: %s\n", buffer);
memcpy(buffer, vpd->sn, IPR_SERIAL_NUM_LEN);
buffer[IPR_SERIAL_NUM_LEN] = '\0';
ipr_err(" Serial Number: %s\n", buffer);
}
/**
* ipr_log_ext_vpd_compact - Log the passed extended VPD compactly.
* @prefix: string to print at start of printk
* @hostrcb: hostrcb pointer
* @vpd: vendor/product id/sn/wwn struct
*
* Return value:
* none
**/
static void ipr_log_ext_vpd_compact(char *prefix, struct ipr_hostrcb *hostrcb,
struct ipr_ext_vpd *vpd)
{
ipr_log_vpd_compact(prefix, hostrcb, &vpd->vpd);
ipr_hcam_err(hostrcb, "%s WWN: %08X%08X\n", prefix,
be32_to_cpu(vpd->wwid[0]), be32_to_cpu(vpd->wwid[1]));
}
/**
* ipr_log_ext_vpd - Log the passed extended VPD to the error log.
* @vpd: vendor/product id/sn/wwn struct
*
* Return value:
* none
**/
static void ipr_log_ext_vpd(struct ipr_ext_vpd *vpd)
{
ipr_log_vpd(&vpd->vpd);
ipr_err(" WWN: %08X%08X\n", be32_to_cpu(vpd->wwid[0]),
be32_to_cpu(vpd->wwid[1]));
}
/**
* ipr_log_enhanced_cache_error - Log a cache error.
* @ioa_cfg: ioa config struct
* @hostrcb: hostrcb struct
*
* Return value:
* none
**/
static void ipr_log_enhanced_cache_error(struct ipr_ioa_cfg *ioa_cfg,
struct ipr_hostrcb *hostrcb)
{
struct ipr_hostrcb_type_12_error *error;
if (ioa_cfg->sis64)
error = &hostrcb->hcam.u.error64.u.type_12_error;
else
error = &hostrcb->hcam.u.error.u.type_12_error;
ipr_err("-----Current Configuration-----\n");
ipr_err("Cache Directory Card Information:\n");
ipr_log_ext_vpd(&error->ioa_vpd);
ipr_err("Adapter Card Information:\n");
ipr_log_ext_vpd(&error->cfc_vpd);
ipr_err("-----Expected Configuration-----\n");
ipr_err("Cache Directory Card Information:\n");
ipr_log_ext_vpd(&error->ioa_last_attached_to_cfc_vpd);
ipr_err("Adapter Card Information:\n");
ipr_log_ext_vpd(&error->cfc_last_attached_to_ioa_vpd);
ipr_err("Additional IOA Data: %08X %08X %08X\n",
be32_to_cpu(error->ioa_data[0]),
be32_to_cpu(error->ioa_data[1]),
be32_to_cpu(error->ioa_data[2]));
}
/**
* ipr_log_cache_error - Log a cache error.
* @ioa_cfg: ioa config struct
* @hostrcb: hostrcb struct
*
* Return value:
* none
**/
static void ipr_log_cache_error(struct ipr_ioa_cfg *ioa_cfg,
struct ipr_hostrcb *hostrcb)
{
struct ipr_hostrcb_type_02_error *error =
&hostrcb->hcam.u.error.u.type_02_error;
ipr_err("-----Current Configuration-----\n");
ipr_err("Cache Directory Card Information:\n");
ipr_log_vpd(&error->ioa_vpd);
ipr_err("Adapter Card Information:\n");
ipr_log_vpd(&error->cfc_vpd);
ipr_err("-----Expected Configuration-----\n");
ipr_err("Cache Directory Card Information:\n");
ipr_log_vpd(&error->ioa_last_attached_to_cfc_vpd);
ipr_err("Adapter Card Information:\n");
ipr_log_vpd(&error->cfc_last_attached_to_ioa_vpd);
ipr_err("Additional IOA Data: %08X %08X %08X\n",
be32_to_cpu(error->ioa_data[0]),
be32_to_cpu(error->ioa_data[1]),
be32_to_cpu(error->ioa_data[2]));
}
/**
* ipr_log_enhanced_config_error - Log a configuration error.
* @ioa_cfg: ioa config struct
* @hostrcb: hostrcb struct
*
* Return value:
* none
**/
static void ipr_log_enhanced_config_error(struct ipr_ioa_cfg *ioa_cfg,
struct ipr_hostrcb *hostrcb)
{
int errors_logged, i;
struct ipr_hostrcb_device_data_entry_enhanced *dev_entry;
struct ipr_hostrcb_type_13_error *error;
error = &hostrcb->hcam.u.error.u.type_13_error;
errors_logged = be32_to_cpu(error->errors_logged);
ipr_err("Device Errors Detected/Logged: %d/%d\n",
be32_to_cpu(error->errors_detected), errors_logged);
dev_entry = error->dev;
for (i = 0; i < errors_logged; i++, dev_entry++) {
ipr_err_separator;
ipr_phys_res_err(ioa_cfg, dev_entry->dev_res_addr, "Device %d", i + 1);
ipr_log_ext_vpd(&dev_entry->vpd);
ipr_err("-----New Device Information-----\n");
ipr_log_ext_vpd(&dev_entry->new_vpd);
ipr_err("Cache Directory Card Information:\n");
ipr_log_ext_vpd(&dev_entry->ioa_last_with_dev_vpd);
ipr_err("Adapter Card Information:\n");
ipr_log_ext_vpd(&dev_entry->cfc_last_with_dev_vpd);
}
}
/**
* ipr_log_sis64_config_error - Log a device error.
* @ioa_cfg: ioa config struct
* @hostrcb: hostrcb struct
*
* Return value:
* none
**/
static void ipr_log_sis64_config_error(struct ipr_ioa_cfg *ioa_cfg,
struct ipr_hostrcb *hostrcb)
{
int errors_logged, i;
struct ipr_hostrcb64_device_data_entry_enhanced *dev_entry;
struct ipr_hostrcb_type_23_error *error;
char buffer[IPR_MAX_RES_PATH_LENGTH];
error = &hostrcb->hcam.u.error64.u.type_23_error;
errors_logged = be32_to_cpu(error->errors_logged);
ipr_err("Device Errors Detected/Logged: %d/%d\n",
be32_to_cpu(error->errors_detected), errors_logged);
dev_entry = error->dev;
for (i = 0; i < errors_logged; i++, dev_entry++) {
ipr_err_separator;
ipr_err("Device %d : %s", i + 1,
ipr_format_res_path(dev_entry->res_path, buffer,
sizeof(buffer)));
ipr_log_ext_vpd(&dev_entry->vpd);
ipr_err("-----New Device Information-----\n");
ipr_log_ext_vpd(&dev_entry->new_vpd);
ipr_err("Cache Directory Card Information:\n");
ipr_log_ext_vpd(&dev_entry->ioa_last_with_dev_vpd);
ipr_err("Adapter Card Information:\n");
ipr_log_ext_vpd(&dev_entry->cfc_last_with_dev_vpd);
}
}
/**
* ipr_log_config_error - Log a configuration error.
* @ioa_cfg: ioa config struct
* @hostrcb: hostrcb struct
*
* Return value:
* none
**/
static void ipr_log_config_error(struct ipr_ioa_cfg *ioa_cfg,
struct ipr_hostrcb *hostrcb)
{
int errors_logged, i;
struct ipr_hostrcb_device_data_entry *dev_entry;
struct ipr_hostrcb_type_03_error *error;
error = &hostrcb->hcam.u.error.u.type_03_error;
errors_logged = be32_to_cpu(error->errors_logged);
ipr_err("Device Errors Detected/Logged: %d/%d\n",
be32_to_cpu(error->errors_detected), errors_logged);
dev_entry = error->dev;
for (i = 0; i < errors_logged; i++, dev_entry++) {
ipr_err_separator;
ipr_phys_res_err(ioa_cfg, dev_entry->dev_res_addr, "Device %d", i + 1);
ipr_log_vpd(&dev_entry->vpd);
ipr_err("-----New Device Information-----\n");
ipr_log_vpd(&dev_entry->new_vpd);
ipr_err("Cache Directory Card Information:\n");
ipr_log_vpd(&dev_entry->ioa_last_with_dev_vpd);
ipr_err("Adapter Card Information:\n");
ipr_log_vpd(&dev_entry->cfc_last_with_dev_vpd);
ipr_err("Additional IOA Data: %08X %08X %08X %08X %08X\n",
be32_to_cpu(dev_entry->ioa_data[0]),
be32_to_cpu(dev_entry->ioa_data[1]),
be32_to_cpu(dev_entry->ioa_data[2]),
be32_to_cpu(dev_entry->ioa_data[3]),
be32_to_cpu(dev_entry->ioa_data[4]));
}
}
/**
* ipr_log_enhanced_array_error - Log an array configuration error.
* @ioa_cfg: ioa config struct
* @hostrcb: hostrcb struct
*
* Return value:
* none
**/
static void ipr_log_enhanced_array_error(struct ipr_ioa_cfg *ioa_cfg,
struct ipr_hostrcb *hostrcb)
{
int i, num_entries;
struct ipr_hostrcb_type_14_error *error;
struct ipr_hostrcb_array_data_entry_enhanced *array_entry;
const u8 zero_sn[IPR_SERIAL_NUM_LEN] = { [0 ... IPR_SERIAL_NUM_LEN-1] = '0' };
error = &hostrcb->hcam.u.error.u.type_14_error;
ipr_err_separator;
ipr_err("RAID %s Array Configuration: %d:%d:%d:%d\n",
error->protection_level,
ioa_cfg->host->host_no,
error->last_func_vset_res_addr.bus,
error->last_func_vset_res_addr.target,
error->last_func_vset_res_addr.lun);
ipr_err_separator;
array_entry = error->array_member;
num_entries = min_t(u32, be32_to_cpu(error->num_entries),
ARRAY_SIZE(error->array_member));
for (i = 0; i < num_entries; i++, array_entry++) {
if (!memcmp(array_entry->vpd.vpd.sn, zero_sn, IPR_SERIAL_NUM_LEN))
continue;
if (be32_to_cpu(error->exposed_mode_adn) == i)
ipr_err("Exposed Array Member %d:\n", i);
else
ipr_err("Array Member %d:\n", i);
ipr_log_ext_vpd(&array_entry->vpd);
ipr_phys_res_err(ioa_cfg, array_entry->dev_res_addr, "Current Location");
ipr_phys_res_err(ioa_cfg, array_entry->expected_dev_res_addr,
"Expected Location");
ipr_err_separator;
}
}
/**
* ipr_log_array_error - Log an array configuration error.
* @ioa_cfg: ioa config struct
* @hostrcb: hostrcb struct
*
* Return value:
* none
**/
static void ipr_log_array_error(struct ipr_ioa_cfg *ioa_cfg,
struct ipr_hostrcb *hostrcb)
{
int i;
struct ipr_hostrcb_type_04_error *error;
struct ipr_hostrcb_array_data_entry *array_entry;
const u8 zero_sn[IPR_SERIAL_NUM_LEN] = { [0 ... IPR_SERIAL_NUM_LEN-1] = '0' };
error = &hostrcb->hcam.u.error.u.type_04_error;
ipr_err_separator;
ipr_err("RAID %s Array Configuration: %d:%d:%d:%d\n",
error->protection_level,
ioa_cfg->host->host_no,
error->last_func_vset_res_addr.bus,
error->last_func_vset_res_addr.target,
error->last_func_vset_res_addr.lun);
ipr_err_separator;
array_entry = error->array_member;
for (i = 0; i < 18; i++) {
if (!memcmp(array_entry->vpd.sn, zero_sn, IPR_SERIAL_NUM_LEN))
continue;
if (be32_to_cpu(error->exposed_mode_adn) == i)
ipr_err("Exposed Array Member %d:\n", i);
else
ipr_err("Array Member %d:\n", i);
ipr_log_vpd(&array_entry->vpd);
ipr_phys_res_err(ioa_cfg, array_entry->dev_res_addr, "Current Location");
ipr_phys_res_err(ioa_cfg, array_entry->expected_dev_res_addr,
"Expected Location");
ipr_err_separator;
if (i == 9)
array_entry = error->array_member2;
else
array_entry++;
}
}
/**
* ipr_log_hex_data - Log additional hex IOA error data.
* @ioa_cfg: ioa config struct
* @data: IOA error data
* @len: data length
*
* Return value:
* none
**/
static void ipr_log_hex_data(struct ipr_ioa_cfg *ioa_cfg, u32 *data, int len)
{
int i;
if (len == 0)
return;
if (ioa_cfg->log_level <= IPR_DEFAULT_LOG_LEVEL)
len = min_t(int, len, IPR_DEFAULT_MAX_ERROR_DUMP);
for (i = 0; i < len / 4; i += 4) {
ipr_err("%08X: %08X %08X %08X %08X\n", i*4,
be32_to_cpu(data[i]),
be32_to_cpu(data[i+1]),
be32_to_cpu(data[i+2]),
be32_to_cpu(data[i+3]));
}
}
/**
* ipr_log_enhanced_dual_ioa_error - Log an enhanced dual adapter error.
* @ioa_cfg: ioa config struct
* @hostrcb: hostrcb struct
*
* Return value:
* none
**/
static void ipr_log_enhanced_dual_ioa_error(struct ipr_ioa_cfg *ioa_cfg,
struct ipr_hostrcb *hostrcb)
{
struct ipr_hostrcb_type_17_error *error;
if (ioa_cfg->sis64)
error = &hostrcb->hcam.u.error64.u.type_17_error;
else
error = &hostrcb->hcam.u.error.u.type_17_error;
error->failure_reason[sizeof(error->failure_reason) - 1] = '\0';
strim(error->failure_reason);
ipr_hcam_err(hostrcb, "%s [PRC: %08X]\n", error->failure_reason,
be32_to_cpu(hostrcb->hcam.u.error.prc));
ipr_log_ext_vpd_compact("Remote IOA", hostrcb, &error->vpd);
ipr_log_hex_data(ioa_cfg, error->data,
be32_to_cpu(hostrcb->hcam.length) -
(offsetof(struct ipr_hostrcb_error, u) +
offsetof(struct ipr_hostrcb_type_17_error, data)));
}
/**
* ipr_log_dual_ioa_error - Log a dual adapter error.
* @ioa_cfg: ioa config struct
* @hostrcb: hostrcb struct
*
* Return value:
* none
**/
static void ipr_log_dual_ioa_error(struct ipr_ioa_cfg *ioa_cfg,
struct ipr_hostrcb *hostrcb)
{
struct ipr_hostrcb_type_07_error *error;
error = &hostrcb->hcam.u.error.u.type_07_error;
error->failure_reason[sizeof(error->failure_reason) - 1] = '\0';
strim(error->failure_reason);
ipr_hcam_err(hostrcb, "%s [PRC: %08X]\n", error->failure_reason,
be32_to_cpu(hostrcb->hcam.u.error.prc));
ipr_log_vpd_compact("Remote IOA", hostrcb, &error->vpd);
ipr_log_hex_data(ioa_cfg, error->data,
be32_to_cpu(hostrcb->hcam.length) -
(offsetof(struct ipr_hostrcb_error, u) +
offsetof(struct ipr_hostrcb_type_07_error, data)));
}
static const struct {
u8 active;
char *desc;
} path_active_desc[] = {
{ IPR_PATH_NO_INFO, "Path" },
{ IPR_PATH_ACTIVE, "Active path" },
{ IPR_PATH_NOT_ACTIVE, "Inactive path" }
};
static const struct {
u8 state;
char *desc;
} path_state_desc[] = {
{ IPR_PATH_STATE_NO_INFO, "has no path state information available" },
{ IPR_PATH_HEALTHY, "is healthy" },
{ IPR_PATH_DEGRADED, "is degraded" },
{ IPR_PATH_FAILED, "is failed" }
};
/**
* ipr_log_fabric_path - Log a fabric path error
* @hostrcb: hostrcb struct
* @fabric: fabric descriptor
*
* Return value:
* none
**/
static void ipr_log_fabric_path(struct ipr_hostrcb *hostrcb,
struct ipr_hostrcb_fabric_desc *fabric)
{
int i, j;
u8 path_state = fabric->path_state;
u8 active = path_state & IPR_PATH_ACTIVE_MASK;
u8 state = path_state & IPR_PATH_STATE_MASK;
for (i = 0; i < ARRAY_SIZE(path_active_desc); i++) {
if (path_active_desc[i].active != active)
continue;
for (j = 0; j < ARRAY_SIZE(path_state_desc); j++) {
if (path_state_desc[j].state != state)
continue;
if (fabric->cascaded_expander == 0xff && fabric->phy == 0xff) {
ipr_hcam_err(hostrcb, "%s %s: IOA Port=%d\n",
path_active_desc[i].desc, path_state_desc[j].desc,
fabric->ioa_port);
} else if (fabric->cascaded_expander == 0xff) {
ipr_hcam_err(hostrcb, "%s %s: IOA Port=%d, Phy=%d\n",
path_active_desc[i].desc, path_state_desc[j].desc,
fabric->ioa_port, fabric->phy);
} else if (fabric->phy == 0xff) {
ipr_hcam_err(hostrcb, "%s %s: IOA Port=%d, Cascade=%d\n",
path_active_desc[i].desc, path_state_desc[j].desc,
fabric->ioa_port, fabric->cascaded_expander);
} else {
ipr_hcam_err(hostrcb, "%s %s: IOA Port=%d, Cascade=%d, Phy=%d\n",
path_active_desc[i].desc, path_state_desc[j].desc,
fabric->ioa_port, fabric->cascaded_expander, fabric->phy);
}
return;
}
}
ipr_err("Path state=%02X IOA Port=%d Cascade=%d Phy=%d\n", path_state,
fabric->ioa_port, fabric->cascaded_expander, fabric->phy);
}
/**
* ipr_log64_fabric_path - Log a fabric path error
* @hostrcb: hostrcb struct
* @fabric: fabric descriptor
*
* Return value:
* none
**/
static void ipr_log64_fabric_path(struct ipr_hostrcb *hostrcb,
struct ipr_hostrcb64_fabric_desc *fabric)
{
int i, j;
u8 path_state = fabric->path_state;
u8 active = path_state & IPR_PATH_ACTIVE_MASK;
u8 state = path_state & IPR_PATH_STATE_MASK;
char buffer[IPR_MAX_RES_PATH_LENGTH];
for (i = 0; i < ARRAY_SIZE(path_active_desc); i++) {
if (path_active_desc[i].active != active)
continue;
for (j = 0; j < ARRAY_SIZE(path_state_desc); j++) {
if (path_state_desc[j].state != state)
continue;
ipr_hcam_err(hostrcb, "%s %s: Resource Path=%s\n",
path_active_desc[i].desc, path_state_desc[j].desc,
ipr_format_res_path(fabric->res_path, buffer,
sizeof(buffer)));
return;
}
}
ipr_err("Path state=%02X Resource Path=%s\n", path_state,
ipr_format_res_path(fabric->res_path, buffer, sizeof(buffer)));
}
static const struct {
u8 type;
char *desc;
} path_type_desc[] = {
{ IPR_PATH_CFG_IOA_PORT, "IOA port" },
{ IPR_PATH_CFG_EXP_PORT, "Expander port" },
{ IPR_PATH_CFG_DEVICE_PORT, "Device port" },
{ IPR_PATH_CFG_DEVICE_LUN, "Device LUN" }
};
static const struct {
u8 status;
char *desc;
} path_status_desc[] = {
{ IPR_PATH_CFG_NO_PROB, "Functional" },
{ IPR_PATH_CFG_DEGRADED, "Degraded" },
{ IPR_PATH_CFG_FAILED, "Failed" },
{ IPR_PATH_CFG_SUSPECT, "Suspect" },
{ IPR_PATH_NOT_DETECTED, "Missing" },
{ IPR_PATH_INCORRECT_CONN, "Incorrectly connected" }
};
static const char *link_rate[] = {
"unknown",
"disabled",
"phy reset problem",
"spinup hold",
"port selector",
"unknown",
"unknown",
"unknown",
"1.5Gbps",
"3.0Gbps",
"unknown",
"unknown",
"unknown",
"unknown",
"unknown",
"unknown"
};
/**
* ipr_log_path_elem - Log a fabric path element.
* @hostrcb: hostrcb struct
* @cfg: fabric path element struct
*
* Return value:
* none
**/
static void ipr_log_path_elem(struct ipr_hostrcb *hostrcb,
struct ipr_hostrcb_config_element *cfg)
{
int i, j;
u8 type = cfg->type_status & IPR_PATH_CFG_TYPE_MASK;
u8 status = cfg->type_status & IPR_PATH_CFG_STATUS_MASK;
if (type == IPR_PATH_CFG_NOT_EXIST)
return;
for (i = 0; i < ARRAY_SIZE(path_type_desc); i++) {
if (path_type_desc[i].type != type)
continue;
for (j = 0; j < ARRAY_SIZE(path_status_desc); j++) {
if (path_status_desc[j].status != status)
continue;
if (type == IPR_PATH_CFG_IOA_PORT) {
ipr_hcam_err(hostrcb, "%s %s: Phy=%d, Link rate=%s, WWN=%08X%08X\n",
path_status_desc[j].desc, path_type_desc[i].desc,
cfg->phy, link_rate[cfg->link_rate & IPR_PHY_LINK_RATE_MASK],
be32_to_cpu(cfg->wwid[0]), be32_to_cpu(cfg->wwid[1]));
} else {
if (cfg->cascaded_expander == 0xff && cfg->phy == 0xff) {
ipr_hcam_err(hostrcb, "%s %s: Link rate=%s, WWN=%08X%08X\n",
path_status_desc[j].desc, path_type_desc[i].desc,
link_rate[cfg->link_rate & IPR_PHY_LINK_RATE_MASK],
be32_to_cpu(cfg->wwid[0]), be32_to_cpu(cfg->wwid[1]));
} else if (cfg->cascaded_expander == 0xff) {
ipr_hcam_err(hostrcb, "%s %s: Phy=%d, Link rate=%s, "
"WWN=%08X%08X\n", path_status_desc[j].desc,
path_type_desc[i].desc, cfg->phy,
link_rate[cfg->link_rate & IPR_PHY_LINK_RATE_MASK],
be32_to_cpu(cfg->wwid[0]), be32_to_cpu(cfg->wwid[1]));
} else if (cfg->phy == 0xff) {
ipr_hcam_err(hostrcb, "%s %s: Cascade=%d, Link rate=%s, "
"WWN=%08X%08X\n", path_status_desc[j].desc,
path_type_desc[i].desc, cfg->cascaded_expander,
link_rate[cfg->link_rate & IPR_PHY_LINK_RATE_MASK],
be32_to_cpu(cfg->wwid[0]), be32_to_cpu(cfg->wwid[1]));
} else {
ipr_hcam_err(hostrcb, "%s %s: Cascade=%d, Phy=%d, Link rate=%s "
"WWN=%08X%08X\n", path_status_desc[j].desc,
path_type_desc[i].desc, cfg->cascaded_expander, cfg->phy,
link_rate[cfg->link_rate & IPR_PHY_LINK_RATE_MASK],
be32_to_cpu(cfg->wwid[0]), be32_to_cpu(cfg->wwid[1]));
}
}
return;
}
}
ipr_hcam_err(hostrcb, "Path element=%02X: Cascade=%d Phy=%d Link rate=%s "
"WWN=%08X%08X\n", cfg->type_status, cfg->cascaded_expander, cfg->phy,
link_rate[cfg->link_rate & IPR_PHY_LINK_RATE_MASK],
be32_to_cpu(cfg->wwid[0]), be32_to_cpu(cfg->wwid[1]));
}
/**
* ipr_log64_path_elem - Log a fabric path element.
* @hostrcb: hostrcb struct
* @cfg: fabric path element struct
*
* Return value:
* none
**/
static void ipr_log64_path_elem(struct ipr_hostrcb *hostrcb,
struct ipr_hostrcb64_config_element *cfg)
{
int i, j;
u8 desc_id = cfg->descriptor_id & IPR_DESCRIPTOR_MASK;
u8 type = cfg->type_status & IPR_PATH_CFG_TYPE_MASK;
u8 status = cfg->type_status & IPR_PATH_CFG_STATUS_MASK;
char buffer[IPR_MAX_RES_PATH_LENGTH];
if (type == IPR_PATH_CFG_NOT_EXIST || desc_id != IPR_DESCRIPTOR_SIS64)
return;
for (i = 0; i < ARRAY_SIZE(path_type_desc); i++) {
if (path_type_desc[i].type != type)
continue;
for (j = 0; j < ARRAY_SIZE(path_status_desc); j++) {
if (path_status_desc[j].status != status)
continue;
ipr_hcam_err(hostrcb, "%s %s: Resource Path=%s, Link rate=%s, WWN=%08X%08X\n",
path_status_desc[j].desc, path_type_desc[i].desc,
ipr_format_res_path(cfg->res_path, buffer,
sizeof(buffer)),
link_rate[cfg->link_rate & IPR_PHY_LINK_RATE_MASK],
be32_to_cpu(cfg->wwid[0]), be32_to_cpu(cfg->wwid[1]));
return;
}
}
ipr_hcam_err(hostrcb, "Path element=%02X: Resource Path=%s, Link rate=%s "
"WWN=%08X%08X\n", cfg->type_status,
ipr_format_res_path(cfg->res_path, buffer, sizeof(buffer)),
link_rate[cfg->link_rate & IPR_PHY_LINK_RATE_MASK],
be32_to_cpu(cfg->wwid[0]), be32_to_cpu(cfg->wwid[1]));
}
/**
* ipr_log_fabric_error - Log a fabric error.
* @ioa_cfg: ioa config struct
* @hostrcb: hostrcb struct
*
* Return value:
* none
**/
static void ipr_log_fabric_error(struct ipr_ioa_cfg *ioa_cfg,
struct ipr_hostrcb *hostrcb)
{
struct ipr_hostrcb_type_20_error *error;
struct ipr_hostrcb_fabric_desc *fabric;
struct ipr_hostrcb_config_element *cfg;
int i, add_len;
error = &hostrcb->hcam.u.error.u.type_20_error;
error->failure_reason[sizeof(error->failure_reason) - 1] = '\0';
ipr_hcam_err(hostrcb, "%s\n", error->failure_reason);
add_len = be32_to_cpu(hostrcb->hcam.length) -
(offsetof(struct ipr_hostrcb_error, u) +
offsetof(struct ipr_hostrcb_type_20_error, desc));
for (i = 0, fabric = error->desc; i < error->num_entries; i++) {
ipr_log_fabric_path(hostrcb, fabric);
for_each_fabric_cfg(fabric, cfg)
ipr_log_path_elem(hostrcb, cfg);
add_len -= be16_to_cpu(fabric->length);
fabric = (struct ipr_hostrcb_fabric_desc *)
((unsigned long)fabric + be16_to_cpu(fabric->length));
}
ipr_log_hex_data(ioa_cfg, (u32 *)fabric, add_len);
}
/**
* ipr_log_sis64_array_error - Log a sis64 array error.
* @ioa_cfg: ioa config struct
* @hostrcb: hostrcb struct
*
* Return value:
* none
**/
static void ipr_log_sis64_array_error(struct ipr_ioa_cfg *ioa_cfg,
struct ipr_hostrcb *hostrcb)
{
int i, num_entries;
struct ipr_hostrcb_type_24_error *error;
struct ipr_hostrcb64_array_data_entry *array_entry;
char buffer[IPR_MAX_RES_PATH_LENGTH];
const u8 zero_sn[IPR_SERIAL_NUM_LEN] = { [0 ... IPR_SERIAL_NUM_LEN-1] = '0' };
error = &hostrcb->hcam.u.error64.u.type_24_error;
ipr_err_separator;
ipr_err("RAID %s Array Configuration: %s\n",
error->protection_level,
ipr_format_res_path(error->last_res_path, buffer, sizeof(buffer)));
ipr_err_separator;
array_entry = error->array_member;
num_entries = min_t(u32, error->num_entries,
ARRAY_SIZE(error->array_member));
for (i = 0; i < num_entries; i++, array_entry++) {
if (!memcmp(array_entry->vpd.vpd.sn, zero_sn, IPR_SERIAL_NUM_LEN))
continue;
if (error->exposed_mode_adn == i)
ipr_err("Exposed Array Member %d:\n", i);
else
ipr_err("Array Member %d:\n", i);
ipr_err("Array Member %d:\n", i);
ipr_log_ext_vpd(&array_entry->vpd);
ipr_err("Current Location: %s\n",
ipr_format_res_path(array_entry->res_path, buffer,
sizeof(buffer)));
ipr_err("Expected Location: %s\n",
ipr_format_res_path(array_entry->expected_res_path,
buffer, sizeof(buffer)));
ipr_err_separator;
}
}
/**
* ipr_log_sis64_fabric_error - Log a sis64 fabric error.
* @ioa_cfg: ioa config struct
* @hostrcb: hostrcb struct
*
* Return value:
* none
**/
static void ipr_log_sis64_fabric_error(struct ipr_ioa_cfg *ioa_cfg,
struct ipr_hostrcb *hostrcb)
{
struct ipr_hostrcb_type_30_error *error;
struct ipr_hostrcb64_fabric_desc *fabric;
struct ipr_hostrcb64_config_element *cfg;
int i, add_len;
error = &hostrcb->hcam.u.error64.u.type_30_error;
error->failure_reason[sizeof(error->failure_reason) - 1] = '\0';
ipr_hcam_err(hostrcb, "%s\n", error->failure_reason);
add_len = be32_to_cpu(hostrcb->hcam.length) -
(offsetof(struct ipr_hostrcb64_error, u) +
offsetof(struct ipr_hostrcb_type_30_error, desc));
for (i = 0, fabric = error->desc; i < error->num_entries; i++) {
ipr_log64_fabric_path(hostrcb, fabric);
for_each_fabric_cfg(fabric, cfg)
ipr_log64_path_elem(hostrcb, cfg);
add_len -= be16_to_cpu(fabric->length);
fabric = (struct ipr_hostrcb64_fabric_desc *)
((unsigned long)fabric + be16_to_cpu(fabric->length));
}
ipr_log_hex_data(ioa_cfg, (u32 *)fabric, add_len);
}
/**
* ipr_log_generic_error - Log an adapter error.
* @ioa_cfg: ioa config struct
* @hostrcb: hostrcb struct
*
* Return value:
* none
**/
static void ipr_log_generic_error(struct ipr_ioa_cfg *ioa_cfg,
struct ipr_hostrcb *hostrcb)
{
ipr_log_hex_data(ioa_cfg, hostrcb->hcam.u.raw.data,
be32_to_cpu(hostrcb->hcam.length));
}
/**
* ipr_get_error - Find the specfied IOASC in the ipr_error_table.
* @ioasc: IOASC
*
* This function will return the index of into the ipr_error_table
* for the specified IOASC. If the IOASC is not in the table,
* 0 will be returned, which points to the entry used for unknown errors.
*
* Return value:
* index into the ipr_error_table
**/
static u32 ipr_get_error(u32 ioasc)
{
int i;
for (i = 0; i < ARRAY_SIZE(ipr_error_table); i++)
if (ipr_error_table[i].ioasc == (ioasc & IPR_IOASC_IOASC_MASK))
return i;
return 0;
}
/**
* ipr_handle_log_data - Log an adapter error.
* @ioa_cfg: ioa config struct
* @hostrcb: hostrcb struct
*
* This function logs an adapter error to the system.
*
* Return value:
* none
**/
static void ipr_handle_log_data(struct ipr_ioa_cfg *ioa_cfg,
struct ipr_hostrcb *hostrcb)
{
u32 ioasc;
int error_index;
if (hostrcb->hcam.notify_type != IPR_HOST_RCB_NOTIF_TYPE_ERROR_LOG_ENTRY)
return;
if (hostrcb->hcam.notifications_lost == IPR_HOST_RCB_NOTIFICATIONS_LOST)
dev_err(&ioa_cfg->pdev->dev, "Error notifications lost\n");
if (ioa_cfg->sis64)
ioasc = be32_to_cpu(hostrcb->hcam.u.error64.fd_ioasc);
else
ioasc = be32_to_cpu(hostrcb->hcam.u.error.fd_ioasc);
if (!ioa_cfg->sis64 && (ioasc == IPR_IOASC_BUS_WAS_RESET ||
ioasc == IPR_IOASC_BUS_WAS_RESET_BY_OTHER)) {
/* Tell the midlayer we had a bus reset so it will handle the UA properly */
scsi_report_bus_reset(ioa_cfg->host,
hostrcb->hcam.u.error.fd_res_addr.bus);
}
error_index = ipr_get_error(ioasc);
if (!ipr_error_table[error_index].log_hcam)
return;
ipr_hcam_err(hostrcb, "%s\n", ipr_error_table[error_index].error);
/* Set indication we have logged an error */
ioa_cfg->errors_logged++;
if (ioa_cfg->log_level < ipr_error_table[error_index].log_hcam)
return;
if (be32_to_cpu(hostrcb->hcam.length) > sizeof(hostrcb->hcam.u.raw))
hostrcb->hcam.length = cpu_to_be32(sizeof(hostrcb->hcam.u.raw));
switch (hostrcb->hcam.overlay_id) {
case IPR_HOST_RCB_OVERLAY_ID_2:
ipr_log_cache_error(ioa_cfg, hostrcb);
break;
case IPR_HOST_RCB_OVERLAY_ID_3:
ipr_log_config_error(ioa_cfg, hostrcb);
break;
case IPR_HOST_RCB_OVERLAY_ID_4:
case IPR_HOST_RCB_OVERLAY_ID_6:
ipr_log_array_error(ioa_cfg, hostrcb);
break;
case IPR_HOST_RCB_OVERLAY_ID_7:
ipr_log_dual_ioa_error(ioa_cfg, hostrcb);
break;
case IPR_HOST_RCB_OVERLAY_ID_12:
ipr_log_enhanced_cache_error(ioa_cfg, hostrcb);
break;
case IPR_HOST_RCB_OVERLAY_ID_13:
ipr_log_enhanced_config_error(ioa_cfg, hostrcb);
break;
case IPR_HOST_RCB_OVERLAY_ID_14:
case IPR_HOST_RCB_OVERLAY_ID_16:
ipr_log_enhanced_array_error(ioa_cfg, hostrcb);
break;
case IPR_HOST_RCB_OVERLAY_ID_17:
ipr_log_enhanced_dual_ioa_error(ioa_cfg, hostrcb);
break;
case IPR_HOST_RCB_OVERLAY_ID_20:
ipr_log_fabric_error(ioa_cfg, hostrcb);
break;
case IPR_HOST_RCB_OVERLAY_ID_23:
ipr_log_sis64_config_error(ioa_cfg, hostrcb);
break;
case IPR_HOST_RCB_OVERLAY_ID_24:
case IPR_HOST_RCB_OVERLAY_ID_26:
ipr_log_sis64_array_error(ioa_cfg, hostrcb);
break;
case IPR_HOST_RCB_OVERLAY_ID_30:
ipr_log_sis64_fabric_error(ioa_cfg, hostrcb);
break;
case IPR_HOST_RCB_OVERLAY_ID_1:
case IPR_HOST_RCB_OVERLAY_ID_DEFAULT:
default:
ipr_log_generic_error(ioa_cfg, hostrcb);
break;
}
}
/**
* ipr_process_error - Op done function for an adapter error log.
* @ipr_cmd: ipr command struct
*
* This function is the op done function for an error log host
* controlled async from the adapter. It will log the error and
* send the HCAM back to the adapter.
*
* Return value:
* none
**/
static void ipr_process_error(struct ipr_cmnd *ipr_cmd)
{
struct ipr_ioa_cfg *ioa_cfg = ipr_cmd->ioa_cfg;
struct ipr_hostrcb *hostrcb = ipr_cmd->u.hostrcb;
u32 ioasc = be32_to_cpu(ipr_cmd->s.ioasa.hdr.ioasc);
u32 fd_ioasc;
if (ioa_cfg->sis64)
fd_ioasc = be32_to_cpu(hostrcb->hcam.u.error64.fd_ioasc);
else
fd_ioasc = be32_to_cpu(hostrcb->hcam.u.error.fd_ioasc);
list_del(&hostrcb->queue);
list_add_tail(&ipr_cmd->queue, &ioa_cfg->free_q);
if (!ioasc) {
ipr_handle_log_data(ioa_cfg, hostrcb);
if (fd_ioasc == IPR_IOASC_NR_IOA_RESET_REQUIRED)
ipr_initiate_ioa_reset(ioa_cfg, IPR_SHUTDOWN_ABBREV);
} else if (ioasc != IPR_IOASC_IOA_WAS_RESET) {
dev_err(&ioa_cfg->pdev->dev,
"Host RCB failed with IOASC: 0x%08X\n", ioasc);
}
ipr_send_hcam(ioa_cfg, IPR_HCAM_CDB_OP_CODE_LOG_DATA, hostrcb);
}
/**
* ipr_timeout - An internally generated op has timed out.
* @ipr_cmd: ipr command struct
*
* This function blocks host requests and initiates an
* adapter reset.
*
* Return value:
* none
**/
static void ipr_timeout(struct ipr_cmnd *ipr_cmd)
{
unsigned long lock_flags = 0;
struct ipr_ioa_cfg *ioa_cfg = ipr_cmd->ioa_cfg;
ENTER;
spin_lock_irqsave(ioa_cfg->host->host_lock, lock_flags);
ioa_cfg->errors_logged++;
dev_err(&ioa_cfg->pdev->dev,
"Adapter being reset due to command timeout.\n");
if (WAIT_FOR_DUMP == ioa_cfg->sdt_state)
ioa_cfg->sdt_state = GET_DUMP;
if (!ioa_cfg->in_reset_reload || ioa_cfg->reset_cmd == ipr_cmd)
ipr_initiate_ioa_reset(ioa_cfg, IPR_SHUTDOWN_NONE);
spin_unlock_irqrestore(ioa_cfg->host->host_lock, lock_flags);
LEAVE;
}
/**
* ipr_oper_timeout - Adapter timed out transitioning to operational
* @ipr_cmd: ipr command struct
*
* This function blocks host requests and initiates an
* adapter reset.
*
* Return value:
* none
**/
static void ipr_oper_timeout(struct ipr_cmnd *ipr_cmd)
{
unsigned long lock_flags = 0;
struct ipr_ioa_cfg *ioa_cfg = ipr_cmd->ioa_cfg;
ENTER;
spin_lock_irqsave(ioa_cfg->host->host_lock, lock_flags);
ioa_cfg->errors_logged++;
dev_err(&ioa_cfg->pdev->dev,
"Adapter timed out transitioning to operational.\n");
if (WAIT_FOR_DUMP == ioa_cfg->sdt_state)
ioa_cfg->sdt_state = GET_DUMP;
if (!ioa_cfg->in_reset_reload || ioa_cfg->reset_cmd == ipr_cmd) {
if (ipr_fastfail)
ioa_cfg->reset_retries += IPR_NUM_RESET_RELOAD_RETRIES;
ipr_initiate_ioa_reset(ioa_cfg, IPR_SHUTDOWN_NONE);
}
spin_unlock_irqrestore(ioa_cfg->host->host_lock, lock_flags);
LEAVE;
}
/**
* ipr_reset_reload - Reset/Reload the IOA
* @ioa_cfg: ioa config struct
* @shutdown_type: shutdown type
*
* This function resets the adapter and re-initializes it.
* This function assumes that all new host commands have been stopped.
* Return value:
* SUCCESS / FAILED
**/
static int ipr_reset_reload(struct ipr_ioa_cfg *ioa_cfg,
enum ipr_shutdown_type shutdown_type)
{
if (!ioa_cfg->in_reset_reload)
ipr_initiate_ioa_reset(ioa_cfg, shutdown_type);
spin_unlock_irq(ioa_cfg->host->host_lock);
wait_event(ioa_cfg->reset_wait_q, !ioa_cfg->in_reset_reload);
spin_lock_irq(ioa_cfg->host->host_lock);
/* If we got hit with a host reset while we were already resetting
the adapter for some reason, and the reset failed. */
if (ioa_cfg->ioa_is_dead) {
ipr_trace;
return FAILED;
}
return SUCCESS;
}
/**
* ipr_find_ses_entry - Find matching SES in SES table
* @res: resource entry struct of SES
*
* Return value:
* pointer to SES table entry / NULL on failure
**/
static const struct ipr_ses_table_entry *
ipr_find_ses_entry(struct ipr_resource_entry *res)
{
int i, j, matches;
struct ipr_std_inq_vpids *vpids;
const struct ipr_ses_table_entry *ste = ipr_ses_table;
for (i = 0; i < ARRAY_SIZE(ipr_ses_table); i++, ste++) {
for (j = 0, matches = 0; j < IPR_PROD_ID_LEN; j++) {
if (ste->compare_product_id_byte[j] == 'X') {
vpids = &res->std_inq_data.vpids;
if (vpids->product_id[j] == ste->product_id[j])
matches++;
else
break;
} else
matches++;
}
if (matches == IPR_PROD_ID_LEN)
return ste;
}
return NULL;
}
/**
* ipr_get_max_scsi_speed - Determine max SCSI speed for a given bus
* @ioa_cfg: ioa config struct
* @bus: SCSI bus
* @bus_width: bus width
*
* Return value:
* SCSI bus speed in units of 100KHz, 1600 is 160 MHz
* For a 2-byte wide SCSI bus, the maximum transfer speed is
* twice the maximum transfer rate (e.g. for a wide enabled bus,
* max 160MHz = max 320MB/sec).
**/
static u32 ipr_get_max_scsi_speed(struct ipr_ioa_cfg *ioa_cfg, u8 bus, u8 bus_width)
{
struct ipr_resource_entry *res;
const struct ipr_ses_table_entry *ste;
u32 max_xfer_rate = IPR_MAX_SCSI_RATE(bus_width);
/* Loop through each config table entry in the config table buffer */
list_for_each_entry(res, &ioa_cfg->used_res_q, queue) {
if (!(IPR_IS_SES_DEVICE(res->std_inq_data)))
continue;
if (bus != res->bus)
continue;
if (!(ste = ipr_find_ses_entry(res)))
continue;
max_xfer_rate = (ste->max_bus_speed_limit * 10) / (bus_width / 8);
}
return max_xfer_rate;
}
/**
* ipr_wait_iodbg_ack - Wait for an IODEBUG ACK from the IOA
* @ioa_cfg: ioa config struct
* @max_delay: max delay in micro-seconds to wait
*
* Waits for an IODEBUG ACK from the IOA, doing busy looping.
*
* Return value:
* 0 on success / other on failure
**/
static int ipr_wait_iodbg_ack(struct ipr_ioa_cfg *ioa_cfg, int max_delay)
{
volatile u32 pcii_reg;
int delay = 1;
/* Read interrupt reg until IOA signals IO Debug Acknowledge */
while (delay < max_delay) {
pcii_reg = readl(ioa_cfg->regs.sense_interrupt_reg);
if (pcii_reg & IPR_PCII_IO_DEBUG_ACKNOWLEDGE)
return 0;
/* udelay cannot be used if delay is more than a few milliseconds */
if ((delay / 1000) > MAX_UDELAY_MS)
mdelay(delay / 1000);
else
udelay(delay);
delay += delay;
}
return -EIO;
}
/**
* ipr_get_sis64_dump_data_section - Dump IOA memory
* @ioa_cfg: ioa config struct
* @start_addr: adapter address to dump
* @dest: destination kernel buffer
* @length_in_words: length to dump in 4 byte words
*
* Return value:
* 0 on success
**/
static int ipr_get_sis64_dump_data_section(struct ipr_ioa_cfg *ioa_cfg,
u32 start_addr,
__be32 *dest, u32 length_in_words)
{
int i;
for (i = 0; i < length_in_words; i++) {
writel(start_addr+(i*4), ioa_cfg->regs.dump_addr_reg);
*dest = cpu_to_be32(readl(ioa_cfg->regs.dump_data_reg));
dest++;
}
return 0;
}
/**
* ipr_get_ldump_data_section - Dump IOA memory
* @ioa_cfg: ioa config struct
* @start_addr: adapter address to dump
* @dest: destination kernel buffer
* @length_in_words: length to dump in 4 byte words
*
* Return value:
* 0 on success / -EIO on failure
**/
static int ipr_get_ldump_data_section(struct ipr_ioa_cfg *ioa_cfg,
u32 start_addr,
__be32 *dest, u32 length_in_words)
{
volatile u32 temp_pcii_reg;
int i, delay = 0;
if (ioa_cfg->sis64)
return ipr_get_sis64_dump_data_section(ioa_cfg, start_addr,
dest, length_in_words);
/* Write IOA interrupt reg starting LDUMP state */
writel((IPR_UPROCI_RESET_ALERT | IPR_UPROCI_IO_DEBUG_ALERT),
ioa_cfg->regs.set_uproc_interrupt_reg32);
/* Wait for IO debug acknowledge */
if (ipr_wait_iodbg_ack(ioa_cfg,
IPR_LDUMP_MAX_LONG_ACK_DELAY_IN_USEC)) {
dev_err(&ioa_cfg->pdev->dev,
"IOA dump long data transfer timeout\n");
return -EIO;
}
/* Signal LDUMP interlocked - clear IO debug ack */
writel(IPR_PCII_IO_DEBUG_ACKNOWLEDGE,
ioa_cfg->regs.clr_interrupt_reg);
/* Write Mailbox with starting address */
writel(start_addr, ioa_cfg->ioa_mailbox);
/* Signal address valid - clear IOA Reset alert */
writel(IPR_UPROCI_RESET_ALERT,
ioa_cfg->regs.clr_uproc_interrupt_reg32);
for (i = 0; i < length_in_words; i++) {
/* Wait for IO debug acknowledge */
if (ipr_wait_iodbg_ack(ioa_cfg,
IPR_LDUMP_MAX_SHORT_ACK_DELAY_IN_USEC)) {
dev_err(&ioa_cfg->pdev->dev,
"IOA dump short data transfer timeout\n");
return -EIO;
}
/* Read data from mailbox and increment destination pointer */
*dest = cpu_to_be32(readl(ioa_cfg->ioa_mailbox));
dest++;
/* For all but the last word of data, signal data received */
if (i < (length_in_words - 1)) {
/* Signal dump data received - Clear IO debug Ack */
writel(IPR_PCII_IO_DEBUG_ACKNOWLEDGE,
ioa_cfg->regs.clr_interrupt_reg);
}
}
/* Signal end of block transfer. Set reset alert then clear IO debug ack */
writel(IPR_UPROCI_RESET_ALERT,
ioa_cfg->regs.set_uproc_interrupt_reg32);
writel(IPR_UPROCI_IO_DEBUG_ALERT,
ioa_cfg->regs.clr_uproc_interrupt_reg32);
/* Signal dump data received - Clear IO debug Ack */
writel(IPR_PCII_IO_DEBUG_ACKNOWLEDGE,
ioa_cfg->regs.clr_interrupt_reg);
/* Wait for IOA to signal LDUMP exit - IOA reset alert will be cleared */
while (delay < IPR_LDUMP_MAX_SHORT_ACK_DELAY_IN_USEC) {
temp_pcii_reg =
readl(ioa_cfg->regs.sense_uproc_interrupt_reg32);
if (!(temp_pcii_reg & IPR_UPROCI_RESET_ALERT))
return 0;
udelay(10);
delay += 10;
}
return 0;
}
#ifdef CONFIG_SCSI_IPR_DUMP
/**
* ipr_sdt_copy - Copy Smart Dump Table to kernel buffer
* @ioa_cfg: ioa config struct
* @pci_address: adapter address
* @length: length of data to copy
*
* Copy data from PCI adapter to kernel buffer.
* Note: length MUST be a 4 byte multiple
* Return value:
* 0 on success / other on failure
**/
static int ipr_sdt_copy(struct ipr_ioa_cfg *ioa_cfg,
unsigned long pci_address, u32 length)
{
int bytes_copied = 0;
int cur_len, rc, rem_len, rem_page_len, max_dump_size;
__be32 *page;
unsigned long lock_flags = 0;
struct ipr_ioa_dump *ioa_dump = &ioa_cfg->dump->ioa_dump;
if (ioa_cfg->sis64)
max_dump_size = IPR_FMT3_MAX_IOA_DUMP_SIZE;
else
max_dump_size = IPR_FMT2_MAX_IOA_DUMP_SIZE;
while (bytes_copied < length &&
(ioa_dump->hdr.len + bytes_copied) < max_dump_size) {
if (ioa_dump->page_offset >= PAGE_SIZE ||
ioa_dump->page_offset == 0) {
page = (__be32 *)__get_free_page(GFP_ATOMIC);
if (!page) {
ipr_trace;
return bytes_copied;
}
ioa_dump->page_offset = 0;
ioa_dump->ioa_data[ioa_dump->next_page_index] = page;
ioa_dump->next_page_index++;
} else
page = ioa_dump->ioa_data[ioa_dump->next_page_index - 1];
rem_len = length - bytes_copied;
rem_page_len = PAGE_SIZE - ioa_dump->page_offset;
cur_len = min(rem_len, rem_page_len);
spin_lock_irqsave(ioa_cfg->host->host_lock, lock_flags);
if (ioa_cfg->sdt_state == ABORT_DUMP) {
rc = -EIO;
} else {
rc = ipr_get_ldump_data_section(ioa_cfg,
pci_address + bytes_copied,
&page[ioa_dump->page_offset / 4],
(cur_len / sizeof(u32)));
}
spin_unlock_irqrestore(ioa_cfg->host->host_lock, lock_flags);
if (!rc) {
ioa_dump->page_offset += cur_len;
bytes_copied += cur_len;
} else {
ipr_trace;
break;
}
schedule();
}
return bytes_copied;
}
/**
* ipr_init_dump_entry_hdr - Initialize a dump entry header.
* @hdr: dump entry header struct
*
* Return value:
* nothing
**/
static void ipr_init_dump_entry_hdr(struct ipr_dump_entry_header *hdr)
{
hdr->eye_catcher = IPR_DUMP_EYE_CATCHER;
hdr->num_elems = 1;
hdr->offset = sizeof(*hdr);
hdr->status = IPR_DUMP_STATUS_SUCCESS;
}
/**
* ipr_dump_ioa_type_data - Fill in the adapter type in the dump.
* @ioa_cfg: ioa config struct
* @driver_dump: driver dump struct
*
* Return value:
* nothing
**/
static void ipr_dump_ioa_type_data(struct ipr_ioa_cfg *ioa_cfg,
struct ipr_driver_dump *driver_dump)
{
struct ipr_inquiry_page3 *ucode_vpd = &ioa_cfg->vpd_cbs->page3_data;
ipr_init_dump_entry_hdr(&driver_dump->ioa_type_entry.hdr);
driver_dump->ioa_type_entry.hdr.len =
sizeof(struct ipr_dump_ioa_type_entry) -
sizeof(struct ipr_dump_entry_header);
driver_dump->ioa_type_entry.hdr.data_type = IPR_DUMP_DATA_TYPE_BINARY;
driver_dump->ioa_type_entry.hdr.id = IPR_DUMP_DRIVER_TYPE_ID;
driver_dump->ioa_type_entry.type = ioa_cfg->type;
driver_dump->ioa_type_entry.fw_version = (ucode_vpd->major_release << 24) |
(ucode_vpd->card_type << 16) | (ucode_vpd->minor_release[0] << 8) |
ucode_vpd->minor_release[1];
driver_dump->hdr.num_entries++;
}
/**
* ipr_dump_version_data - Fill in the driver version in the dump.
* @ioa_cfg: ioa config struct
* @driver_dump: driver dump struct
*
* Return value:
* nothing
**/
static void ipr_dump_version_data(struct ipr_ioa_cfg *ioa_cfg,
struct ipr_driver_dump *driver_dump)
{
ipr_init_dump_entry_hdr(&driver_dump->version_entry.hdr);
driver_dump->version_entry.hdr.len =
sizeof(struct ipr_dump_version_entry) -
sizeof(struct ipr_dump_entry_header);
driver_dump->version_entry.hdr.data_type = IPR_DUMP_DATA_TYPE_ASCII;
driver_dump->version_entry.hdr.id = IPR_DUMP_DRIVER_VERSION_ID;
strcpy(driver_dump->version_entry.version, IPR_DRIVER_VERSION);
driver_dump->hdr.num_entries++;
}
/**
* ipr_dump_trace_data - Fill in the IOA trace in the dump.
* @ioa_cfg: ioa config struct
* @driver_dump: driver dump struct
*
* Return value:
* nothing
**/
static void ipr_dump_trace_data(struct ipr_ioa_cfg *ioa_cfg,
struct ipr_driver_dump *driver_dump)
{
ipr_init_dump_entry_hdr(&driver_dump->trace_entry.hdr);
driver_dump->trace_entry.hdr.len =
sizeof(struct ipr_dump_trace_entry) -
sizeof(struct ipr_dump_entry_header);
driver_dump->trace_entry.hdr.data_type = IPR_DUMP_DATA_TYPE_BINARY;
driver_dump->trace_entry.hdr.id = IPR_DUMP_TRACE_ID;
memcpy(driver_dump->trace_entry.trace, ioa_cfg->trace, IPR_TRACE_SIZE);
driver_dump->hdr.num_entries++;
}
/**
* ipr_dump_location_data - Fill in the IOA location in the dump.
* @ioa_cfg: ioa config struct
* @driver_dump: driver dump struct
*
* Return value:
* nothing
**/
static void ipr_dump_location_data(struct ipr_ioa_cfg *ioa_cfg,
struct ipr_driver_dump *driver_dump)
{
ipr_init_dump_entry_hdr(&driver_dump->location_entry.hdr);
driver_dump->location_entry.hdr.len =
sizeof(struct ipr_dump_location_entry) -
sizeof(struct ipr_dump_entry_header);
driver_dump->location_entry.hdr.data_type = IPR_DUMP_DATA_TYPE_ASCII;
driver_dump->location_entry.hdr.id = IPR_DUMP_LOCATION_ID;
strcpy(driver_dump->location_entry.location, dev_name(&ioa_cfg->pdev->dev));
driver_dump->hdr.num_entries++;
}
/**
* ipr_get_ioa_dump - Perform a dump of the driver and adapter.
* @ioa_cfg: ioa config struct
* @dump: dump struct
*
* Return value:
* nothing
**/
static void ipr_get_ioa_dump(struct ipr_ioa_cfg *ioa_cfg, struct ipr_dump *dump)
{
unsigned long start_addr, sdt_word;
unsigned long lock_flags = 0;
struct ipr_driver_dump *driver_dump = &dump->driver_dump;
struct ipr_ioa_dump *ioa_dump = &dump->ioa_dump;
u32 num_entries, max_num_entries, start_off, end_off;
u32 max_dump_size, bytes_to_copy, bytes_copied, rc;
struct ipr_sdt *sdt;
int valid = 1;
int i;
ENTER;
spin_lock_irqsave(ioa_cfg->host->host_lock, lock_flags);
if (ioa_cfg->sdt_state != READ_DUMP) {
spin_unlock_irqrestore(ioa_cfg->host->host_lock, lock_flags);
return;
}
if (ioa_cfg->sis64) {
spin_unlock_irqrestore(ioa_cfg->host->host_lock, lock_flags);
ssleep(IPR_DUMP_DELAY_SECONDS);
spin_lock_irqsave(ioa_cfg->host->host_lock, lock_flags);
}
start_addr = readl(ioa_cfg->ioa_mailbox);
if (!ioa_cfg->sis64 && !ipr_sdt_is_fmt2(start_addr)) {
dev_err(&ioa_cfg->pdev->dev,
"Invalid dump table format: %lx\n", start_addr);
spin_unlock_irqrestore(ioa_cfg->host->host_lock, lock_flags);
return;
}
dev_err(&ioa_cfg->pdev->dev, "Dump of IOA initiated\n");
driver_dump->hdr.eye_catcher = IPR_DUMP_EYE_CATCHER;
/* Initialize the overall dump header */
driver_dump->hdr.len = sizeof(struct ipr_driver_dump);
driver_dump->hdr.num_entries = 1;
driver_dump->hdr.first_entry_offset = sizeof(struct ipr_dump_header);
driver_dump->hdr.status = IPR_DUMP_STATUS_SUCCESS;
driver_dump->hdr.os = IPR_DUMP_OS_LINUX;
driver_dump->hdr.driver_name = IPR_DUMP_DRIVER_NAME;
ipr_dump_version_data(ioa_cfg, driver_dump);
ipr_dump_location_data(ioa_cfg, driver_dump);
ipr_dump_ioa_type_data(ioa_cfg, driver_dump);
ipr_dump_trace_data(ioa_cfg, driver_dump);
/* Update dump_header */
driver_dump->hdr.len += sizeof(struct ipr_dump_entry_header);
/* IOA Dump entry */
ipr_init_dump_entry_hdr(&ioa_dump->hdr);
ioa_dump->hdr.len = 0;
ioa_dump->hdr.data_type = IPR_DUMP_DATA_TYPE_BINARY;
ioa_dump->hdr.id = IPR_DUMP_IOA_DUMP_ID;
/* First entries in sdt are actually a list of dump addresses and
lengths to gather the real dump data. sdt represents the pointer
to the ioa generated dump table. Dump data will be extracted based
on entries in this table */
sdt = &ioa_dump->sdt;
if (ioa_cfg->sis64) {
max_num_entries = IPR_FMT3_NUM_SDT_ENTRIES;
max_dump_size = IPR_FMT3_MAX_IOA_DUMP_SIZE;
} else {
max_num_entries = IPR_FMT2_NUM_SDT_ENTRIES;
max_dump_size = IPR_FMT2_MAX_IOA_DUMP_SIZE;
}
bytes_to_copy = offsetof(struct ipr_sdt, entry) +
(max_num_entries * sizeof(struct ipr_sdt_entry));
rc = ipr_get_ldump_data_section(ioa_cfg, start_addr, (__be32 *)sdt,
bytes_to_copy / sizeof(__be32));
/* Smart Dump table is ready to use and the first entry is valid */
if (rc || ((be32_to_cpu(sdt->hdr.state) != IPR_FMT3_SDT_READY_TO_USE) &&
(be32_to_cpu(sdt->hdr.state) != IPR_FMT2_SDT_READY_TO_USE))) {
dev_err(&ioa_cfg->pdev->dev,
"Dump of IOA failed. Dump table not valid: %d, %X.\n",
rc, be32_to_cpu(sdt->hdr.state));
driver_dump->hdr.status = IPR_DUMP_STATUS_FAILED;
ioa_cfg->sdt_state = DUMP_OBTAINED;
spin_unlock_irqrestore(ioa_cfg->host->host_lock, lock_flags);
return;
}
num_entries = be32_to_cpu(sdt->hdr.num_entries_used);
if (num_entries > max_num_entries)
num_entries = max_num_entries;
/* Update dump length to the actual data to be copied */
dump->driver_dump.hdr.len += sizeof(struct ipr_sdt_header);
if (ioa_cfg->sis64)
dump->driver_dump.hdr.len += num_entries * sizeof(struct ipr_sdt_entry);
else
dump->driver_dump.hdr.len += max_num_entries * sizeof(struct ipr_sdt_entry);
spin_unlock_irqrestore(ioa_cfg->host->host_lock, lock_flags);
for (i = 0; i < num_entries; i++) {
if (ioa_dump->hdr.len > max_dump_size) {
driver_dump->hdr.status = IPR_DUMP_STATUS_QUAL_SUCCESS;
break;
}
if (sdt->entry[i].flags & IPR_SDT_VALID_ENTRY) {
sdt_word = be32_to_cpu(sdt->entry[i].start_token);
if (ioa_cfg->sis64)
bytes_to_copy = be32_to_cpu(sdt->entry[i].end_token);
else {
start_off = sdt_word & IPR_FMT2_MBX_ADDR_MASK;
end_off = be32_to_cpu(sdt->entry[i].end_token);
if (ipr_sdt_is_fmt2(sdt_word) && sdt_word)
bytes_to_copy = end_off - start_off;
else
valid = 0;
}
if (valid) {
if (bytes_to_copy > max_dump_size) {
sdt->entry[i].flags &= ~IPR_SDT_VALID_ENTRY;
continue;
}
/* Copy data from adapter to driver buffers */
bytes_copied = ipr_sdt_copy(ioa_cfg, sdt_word,
bytes_to_copy);
ioa_dump->hdr.len += bytes_copied;
if (bytes_copied != bytes_to_copy) {
driver_dump->hdr.status = IPR_DUMP_STATUS_QUAL_SUCCESS;
break;
}
}
}
}
dev_err(&ioa_cfg->pdev->dev, "Dump of IOA completed.\n");
/* Update dump_header */
driver_dump->hdr.len += ioa_dump->hdr.len;
wmb();
ioa_cfg->sdt_state = DUMP_OBTAINED;
LEAVE;
}