blob: e40528185d48fab70a6d5011ed1a4f6773073cef [file] [log] [blame]
#if (!defined(dprintk))
# define dprintk(x)
#endif
/*------------------------------------------------------------------------------
* D E F I N E S
*----------------------------------------------------------------------------*/
#define MAXIMUM_NUM_CONTAINERS 32
#define AAC_NUM_MGT_FIB 8
#define AAC_NUM_IO_FIB (512 - AAC_NUM_MGT_FIB)
#define AAC_NUM_FIB (AAC_NUM_IO_FIB + AAC_NUM_MGT_FIB)
#define AAC_MAX_LUN (8)
#define AAC_MAX_HOSTPHYSMEMPAGES (0xfffff)
#define AAC_MAX_32BIT_SGBCOUNT ((unsigned short)512)
/*
* These macros convert from physical channels to virtual channels
*/
#define CONTAINER_CHANNEL (0)
#define ID_LUN_TO_CONTAINER(id, lun) (id)
#define CONTAINER_TO_CHANNEL(cont) (CONTAINER_CHANNEL)
#define CONTAINER_TO_ID(cont) (cont)
#define CONTAINER_TO_LUN(cont) (0)
#define aac_phys_to_logical(x) (x+1)
#define aac_logical_to_phys(x) (x?x-1:0)
/* #define AAC_DETAILED_STATUS_INFO */
struct diskparm
{
int heads;
int sectors;
int cylinders;
};
/*
* DON'T CHANGE THE ORDER, this is set by the firmware
*/
#define CT_NONE 0
#define CT_VOLUME 1
#define CT_MIRROR 2
#define CT_STRIPE 3
#define CT_RAID5 4
#define CT_SSRW 5
#define CT_SSRO 6
#define CT_MORPH 7
#define CT_PASSTHRU 8
#define CT_RAID4 9
#define CT_RAID10 10 /* stripe of mirror */
#define CT_RAID00 11 /* stripe of stripe */
#define CT_VOLUME_OF_MIRRORS 12 /* volume of mirror */
#define CT_PSEUDO_RAID 13 /* really raid4 */
#define CT_LAST_VOLUME_TYPE 14
#define CT_OK 218
/*
* Types of objects addressable in some fashion by the client.
* This is a superset of those objects handled just by the filesystem
* and includes "raw" objects that an administrator would use to
* configure containers and filesystems.
*/
#define FT_REG 1 /* regular file */
#define FT_DIR 2 /* directory */
#define FT_BLK 3 /* "block" device - reserved */
#define FT_CHR 4 /* "character special" device - reserved */
#define FT_LNK 5 /* symbolic link */
#define FT_SOCK 6 /* socket */
#define FT_FIFO 7 /* fifo */
#define FT_FILESYS 8 /* ADAPTEC's "FSA"(tm) filesystem */
#define FT_DRIVE 9 /* physical disk - addressable in scsi by bus/id/lun */
#define FT_SLICE 10 /* virtual disk - raw volume - slice */
#define FT_PARTITION 11 /* FSA partition - carved out of a slice - building block for containers */
#define FT_VOLUME 12 /* Container - Volume Set */
#define FT_STRIPE 13 /* Container - Stripe Set */
#define FT_MIRROR 14 /* Container - Mirror Set */
#define FT_RAID5 15 /* Container - Raid 5 Set */
#define FT_DATABASE 16 /* Storage object with "foreign" content manager */
/*
* Host side memory scatter gather list
* Used by the adapter for read, write, and readdirplus operations
* We have separate 32 and 64 bit version because even
* on 64 bit systems not all cards support the 64 bit version
*/
struct sgentry {
__le32 addr; /* 32-bit address. */
__le32 count; /* Length. */
};
struct user_sgentry {
u32 addr; /* 32-bit address. */
u32 count; /* Length. */
};
struct sgentry64 {
__le32 addr[2]; /* 64-bit addr. 2 pieces for data alignment */
__le32 count; /* Length. */
};
struct user_sgentry64 {
u32 addr[2]; /* 64-bit addr. 2 pieces for data alignment */
u32 count; /* Length. */
};
struct sgentryraw {
__le32 next; /* reserved for F/W use */
__le32 prev; /* reserved for F/W use */
__le32 addr[2];
__le32 count;
__le32 flags; /* reserved for F/W use */
};
struct user_sgentryraw {
u32 next; /* reserved for F/W use */
u32 prev; /* reserved for F/W use */
u32 addr[2];
u32 count;
u32 flags; /* reserved for F/W use */
};
/*
* SGMAP
*
* This is the SGMAP structure for all commands that use
* 32-bit addressing.
*/
struct sgmap {
__le32 count;
struct sgentry sg[1];
};
struct user_sgmap {
u32 count;
struct user_sgentry sg[1];
};
struct sgmap64 {
__le32 count;
struct sgentry64 sg[1];
};
struct user_sgmap64 {
u32 count;
struct user_sgentry64 sg[1];
};
struct sgmapraw {
__le32 count;
struct sgentryraw sg[1];
};
struct user_sgmapraw {
u32 count;
struct user_sgentryraw sg[1];
};
struct creation_info
{
u8 buildnum; /* e.g., 588 */
u8 usec; /* e.g., 588 */
u8 via; /* e.g., 1 = FSU,
* 2 = API
*/
u8 year; /* e.g., 1997 = 97 */
__le32 date; /*
* unsigned Month :4; // 1 - 12
* unsigned Day :6; // 1 - 32
* unsigned Hour :6; // 0 - 23
* unsigned Minute :6; // 0 - 60
* unsigned Second :6; // 0 - 60
*/
__le32 serial[2]; /* e.g., 0x1DEADB0BFAFAF001 */
};
/*
* Define all the constants needed for the communication interface
*/
/*
* Define how many queue entries each queue will have and the total
* number of entries for the entire communication interface. Also define
* how many queues we support.
*
* This has to match the controller
*/
#define NUMBER_OF_COMM_QUEUES 8 // 4 command; 4 response
#define HOST_HIGH_CMD_ENTRIES 4
#define HOST_NORM_CMD_ENTRIES 8
#define ADAP_HIGH_CMD_ENTRIES 4
#define ADAP_NORM_CMD_ENTRIES 512
#define HOST_HIGH_RESP_ENTRIES 4
#define HOST_NORM_RESP_ENTRIES 512
#define ADAP_HIGH_RESP_ENTRIES 4
#define ADAP_NORM_RESP_ENTRIES 8
#define TOTAL_QUEUE_ENTRIES \
(HOST_NORM_CMD_ENTRIES + HOST_HIGH_CMD_ENTRIES + ADAP_NORM_CMD_ENTRIES + ADAP_HIGH_CMD_ENTRIES + \
HOST_NORM_RESP_ENTRIES + HOST_HIGH_RESP_ENTRIES + ADAP_NORM_RESP_ENTRIES + ADAP_HIGH_RESP_ENTRIES)
/*
* Set the queues on a 16 byte alignment
*/
#define QUEUE_ALIGNMENT 16
/*
* The queue headers define the Communication Region queues. These
* are physically contiguous and accessible by both the adapter and the
* host. Even though all queue headers are in the same contiguous block
* they will be represented as individual units in the data structures.
*/
struct aac_entry {
__le32 size; /* Size in bytes of Fib which this QE points to */
__le32 addr; /* Receiver address of the FIB */
};
/*
* The adapter assumes the ProducerIndex and ConsumerIndex are grouped
* adjacently and in that order.
*/
struct aac_qhdr {
__le64 header_addr;/* Address to hand the adapter to access
to this queue head */
__le32 *producer; /* The producer index for this queue (host address) */
__le32 *consumer; /* The consumer index for this queue (host address) */
};
/*
* Define all the events which the adapter would like to notify
* the host of.
*/
#define HostNormCmdQue 1 /* Change in host normal priority command queue */
#define HostHighCmdQue 2 /* Change in host high priority command queue */
#define HostNormRespQue 3 /* Change in host normal priority response queue */
#define HostHighRespQue 4 /* Change in host high priority response queue */
#define AdapNormRespNotFull 5
#define AdapHighRespNotFull 6
#define AdapNormCmdNotFull 7
#define AdapHighCmdNotFull 8
#define SynchCommandComplete 9
#define AdapInternalError 0xfe /* The adapter detected an internal error shutting down */
/*
* Define all the events the host wishes to notify the
* adapter of. The first four values much match the Qid the
* corresponding queue.
*/
#define AdapNormCmdQue 2
#define AdapHighCmdQue 3
#define AdapNormRespQue 6
#define AdapHighRespQue 7
#define HostShutdown 8
#define HostPowerFail 9
#define FatalCommError 10
#define HostNormRespNotFull 11
#define HostHighRespNotFull 12
#define HostNormCmdNotFull 13
#define HostHighCmdNotFull 14
#define FastIo 15
#define AdapPrintfDone 16
/*
* Define all the queues that the adapter and host use to communicate
* Number them to match the physical queue layout.
*/
enum aac_queue_types {
HostNormCmdQueue = 0, /* Adapter to host normal priority command traffic */
HostHighCmdQueue, /* Adapter to host high priority command traffic */
AdapNormCmdQueue, /* Host to adapter normal priority command traffic */
AdapHighCmdQueue, /* Host to adapter high priority command traffic */
HostNormRespQueue, /* Adapter to host normal priority response traffic */
HostHighRespQueue, /* Adapter to host high priority response traffic */
AdapNormRespQueue, /* Host to adapter normal priority response traffic */
AdapHighRespQueue /* Host to adapter high priority response traffic */
};
/*
* Assign type values to the FSA communication data structures
*/
#define FIB_MAGIC 0x0001
/*
* Define the priority levels the FSA communication routines support.
*/
#define FsaNormal 1
#define FsaHigh 2
/*
* Define the FIB. The FIB is the where all the requested data and
* command information are put to the application on the FSA adapter.
*/
struct aac_fibhdr {
__le32 XferState; /* Current transfer state for this CCB */
__le16 Command; /* Routing information for the destination */
u8 StructType; /* Type FIB */
u8 Flags; /* Flags for FIB */
__le16 Size; /* Size of this FIB in bytes */
__le16 SenderSize; /* Size of the FIB in the sender
(for response sizing) */
__le32 SenderFibAddress; /* Host defined data in the FIB */
__le32 ReceiverFibAddress;/* Logical address of this FIB for
the adapter */
u32 SenderData; /* Place holder for the sender to store data */
union {
struct {
__le32 _ReceiverTimeStart; /* Timestamp for
receipt of fib */
__le32 _ReceiverTimeDone; /* Timestamp for
completion of fib */
} _s;
} _u;
};
struct hw_fib {
struct aac_fibhdr header;
u8 data[512-sizeof(struct aac_fibhdr)]; // Command specific data
};
/*
* FIB commands
*/
#define TestCommandResponse 1
#define TestAdapterCommand 2
/*
* Lowlevel and comm commands
*/
#define LastTestCommand 100
#define ReinitHostNormCommandQueue 101
#define ReinitHostHighCommandQueue 102
#define ReinitHostHighRespQueue 103
#define ReinitHostNormRespQueue 104
#define ReinitAdapNormCommandQueue 105
#define ReinitAdapHighCommandQueue 107
#define ReinitAdapHighRespQueue 108
#define ReinitAdapNormRespQueue 109
#define InterfaceShutdown 110
#define DmaCommandFib 120
#define StartProfile 121
#define TermProfile 122
#define SpeedTest 123
#define TakeABreakPt 124
#define RequestPerfData 125
#define SetInterruptDefTimer 126
#define SetInterruptDefCount 127
#define GetInterruptDefStatus 128
#define LastCommCommand 129
/*
* Filesystem commands
*/
#define NuFileSystem 300
#define UFS 301
#define HostFileSystem 302
#define LastFileSystemCommand 303
/*
* Container Commands
*/
#define ContainerCommand 500
#define ContainerCommand64 501
#define ContainerRawIo 502
/*
* Cluster Commands
*/
#define ClusterCommand 550
/*
* Scsi Port commands (scsi passthrough)
*/
#define ScsiPortCommand 600
#define ScsiPortCommand64 601
/*
* Misc house keeping and generic adapter initiated commands
*/
#define AifRequest 700
#define CheckRevision 701
#define FsaHostShutdown 702
#define RequestAdapterInfo 703
#define IsAdapterPaused 704
#define SendHostTime 705
#define RequestSupplementAdapterInfo 706
#define LastMiscCommand 707
/*
* Commands that will target the failover level on the FSA adapter
*/
enum fib_xfer_state {
HostOwned = (1<<0),
AdapterOwned = (1<<1),
FibInitialized = (1<<2),
FibEmpty = (1<<3),
AllocatedFromPool = (1<<4),
SentFromHost = (1<<5),
SentFromAdapter = (1<<6),
ResponseExpected = (1<<7),
NoResponseExpected = (1<<8),
AdapterProcessed = (1<<9),
HostProcessed = (1<<10),
HighPriority = (1<<11),
NormalPriority = (1<<12),
Async = (1<<13),
AsyncIo = (1<<13), // rpbfix: remove with new regime
PageFileIo = (1<<14), // rpbfix: remove with new regime
ShutdownRequest = (1<<15),
LazyWrite = (1<<16), // rpbfix: remove with new regime
AdapterMicroFib = (1<<17),
BIOSFibPath = (1<<18),
FastResponseCapable = (1<<19),
ApiFib = (1<<20) // Its an API Fib.
};
/*
* The following defines needs to be updated any time there is an
* incompatible change made to the aac_init structure.
*/
#define ADAPTER_INIT_STRUCT_REVISION 3
#define ADAPTER_INIT_STRUCT_REVISION_4 4 // rocket science
struct aac_init
{
__le32 InitStructRevision;
__le32 MiniPortRevision;
__le32 fsrev;
__le32 CommHeaderAddress;
__le32 FastIoCommAreaAddress;
__le32 AdapterFibsPhysicalAddress;
__le32 AdapterFibsVirtualAddress;
__le32 AdapterFibsSize;
__le32 AdapterFibAlign;
__le32 printfbuf;
__le32 printfbufsiz;
__le32 HostPhysMemPages; /* number of 4k pages of host
physical memory */
__le32 HostElapsedSeconds; /* number of seconds since 1970. */
/*
* ADAPTER_INIT_STRUCT_REVISION_4 begins here
*/
__le32 InitFlags; /* flags for supported features */
#define INITFLAGS_NEW_COMM_SUPPORTED 0x00000001
__le32 MaxIoCommands; /* max outstanding commands */
__le32 MaxIoSize; /* largest I/O command */
__le32 MaxFibSize; /* largest FIB to adapter */
};
enum aac_log_level {
LOG_AAC_INIT = 10,
LOG_AAC_INFORMATIONAL = 20,
LOG_AAC_WARNING = 30,
LOG_AAC_LOW_ERROR = 40,
LOG_AAC_MEDIUM_ERROR = 50,
LOG_AAC_HIGH_ERROR = 60,
LOG_AAC_PANIC = 70,
LOG_AAC_DEBUG = 80,
LOG_AAC_WINDBG_PRINT = 90
};
#define FSAFS_NTC_GET_ADAPTER_FIB_CONTEXT 0x030b
#define FSAFS_NTC_FIB_CONTEXT 0x030c
struct aac_dev;
struct adapter_ops
{
void (*adapter_interrupt)(struct aac_dev *dev);
void (*adapter_notify)(struct aac_dev *dev, u32 event);
void (*adapter_disable_int)(struct aac_dev *dev);
int (*adapter_sync_cmd)(struct aac_dev *dev, u32 command, u32 p1, u32 p2, u32 p3, u32 p4, u32 p5, u32 p6, u32 *status, u32 *r1, u32 *r2, u32 *r3, u32 *r4);
int (*adapter_check_health)(struct aac_dev *dev);
};
/*
* Define which interrupt handler needs to be installed
*/
struct aac_driver_ident
{
int (*init)(struct aac_dev *dev);
char * name;
char * vname;
char * model;
u16 channels;
int quirks;
};
/*
* Some adapter firmware needs communication memory
* below 2gig. This tells the init function to set the
* dma mask such that fib memory will be allocated where the
* adapter firmware can get to it.
*/
#define AAC_QUIRK_31BIT 0x0001
/*
* Some adapter firmware, when the raid card's cache is turned off, can not
* split up scatter gathers in order to deal with the limits of the
* underlying CHIM. This limit is 34 scatter gather elements.
*/
#define AAC_QUIRK_34SG 0x0002
/*
* This adapter is a slave (no Firmware)
*/
#define AAC_QUIRK_SLAVE 0x0004
/*
* This adapter is a master.
*/
#define AAC_QUIRK_MASTER 0x0008
/*
* The adapter interface specs all queues to be located in the same
* physically contigous block. The host structure that defines the
* commuication queues will assume they are each a separate physically
* contigous memory region that will support them all being one big
* contigous block.
* There is a command and response queue for each level and direction of
* commuication. These regions are accessed by both the host and adapter.
*/
struct aac_queue {
u64 logical; /*address we give the adapter */
struct aac_entry *base; /*system virtual address */
struct aac_qhdr headers; /*producer,consumer q headers*/
u32 entries; /*Number of queue entries */
wait_queue_head_t qfull; /*Event to wait on if q full */
wait_queue_head_t cmdready; /*Cmd ready from the adapter */
/* This is only valid for adapter to host command queues. */
spinlock_t *lock; /* Spinlock for this queue must take this lock before accessing the lock */
spinlock_t lockdata; /* Actual lock (used only on one side of the lock) */
unsigned long SavedIrql; /* Previous IRQL when the spin lock is taken */
u32 padding; /* Padding - FIXME - can remove I believe */
struct list_head cmdq; /* A queue of FIBs which need to be prcessed by the FS thread. This is */
/* only valid for command queues which receive entries from the adapter. */
struct list_head pendingq; /* A queue of outstanding fib's to the adapter. */
u32 numpending; /* Number of entries on outstanding queue. */
struct aac_dev * dev; /* Back pointer to adapter structure */
};
/*
* Message queues. The order here is important, see also the
* queue type ordering
*/
struct aac_queue_block
{
struct aac_queue queue[8];
};
/*
* SaP1 Message Unit Registers
*/
struct sa_drawbridge_CSR {
/* Offset | Name */
__le32 reserved[10]; /* 00h-27h | Reserved */
u8 LUT_Offset; /* 28h | Lookup Table Offset */
u8 reserved1[3]; /* 29h-2bh | Reserved */
__le32 LUT_Data; /* 2ch | Looup Table Data */
__le32 reserved2[26]; /* 30h-97h | Reserved */
__le16 PRICLEARIRQ; /* 98h | Primary Clear Irq */
__le16 SECCLEARIRQ; /* 9ah | Secondary Clear Irq */
__le16 PRISETIRQ; /* 9ch | Primary Set Irq */
__le16 SECSETIRQ; /* 9eh | Secondary Set Irq */
__le16 PRICLEARIRQMASK;/* a0h | Primary Clear Irq Mask */
__le16 SECCLEARIRQMASK;/* a2h | Secondary Clear Irq Mask */
__le16 PRISETIRQMASK; /* a4h | Primary Set Irq Mask */
__le16 SECSETIRQMASK; /* a6h | Secondary Set Irq Mask */
__le32 MAILBOX0; /* a8h | Scratchpad 0 */
__le32 MAILBOX1; /* ach | Scratchpad 1 */
__le32 MAILBOX2; /* b0h | Scratchpad 2 */
__le32 MAILBOX3; /* b4h | Scratchpad 3 */
__le32 MAILBOX4; /* b8h | Scratchpad 4 */
__le32 MAILBOX5; /* bch | Scratchpad 5 */
__le32 MAILBOX6; /* c0h | Scratchpad 6 */
__le32 MAILBOX7; /* c4h | Scratchpad 7 */
__le32 ROM_Setup_Data; /* c8h | Rom Setup and Data */
__le32 ROM_Control_Addr;/* cch | Rom Control and Address */
__le32 reserved3[12]; /* d0h-ffh | reserved */
__le32 LUT[64]; /* 100h-1ffh | Lookup Table Entries */
};
#define Mailbox0 SaDbCSR.MAILBOX0
#define Mailbox1 SaDbCSR.MAILBOX1
#define Mailbox2 SaDbCSR.MAILBOX2
#define Mailbox3 SaDbCSR.MAILBOX3
#define Mailbox4 SaDbCSR.MAILBOX4
#define Mailbox5 SaDbCSR.MAILBOX5
#define Mailbox6 SaDbCSR.MAILBOX6
#define Mailbox7 SaDbCSR.MAILBOX7
#define DoorbellReg_p SaDbCSR.PRISETIRQ
#define DoorbellReg_s SaDbCSR.SECSETIRQ
#define DoorbellClrReg_p SaDbCSR.PRICLEARIRQ
#define DOORBELL_0 0x0001
#define DOORBELL_1 0x0002
#define DOORBELL_2 0x0004
#define DOORBELL_3 0x0008
#define DOORBELL_4 0x0010
#define DOORBELL_5 0x0020
#define DOORBELL_6 0x0040
#define PrintfReady DOORBELL_5
#define PrintfDone DOORBELL_5
struct sa_registers {
struct sa_drawbridge_CSR SaDbCSR; /* 98h - c4h */
};
#define Sa_MINIPORT_REVISION 1
#define sa_readw(AEP, CSR) readl(&((AEP)->regs.sa->CSR))
#define sa_readl(AEP, CSR) readl(&((AEP)->regs.sa->CSR))
#define sa_writew(AEP, CSR, value) writew(value, &((AEP)->regs.sa->CSR))
#define sa_writel(AEP, CSR, value) writel(value, &((AEP)->regs.sa->CSR))
/*
* Rx Message Unit Registers
*/
struct rx_mu_registers {
/* Local | PCI*| Name */
__le32 ARSR; /* 1300h | 00h | APIC Register Select Register */
__le32 reserved0; /* 1304h | 04h | Reserved */
__le32 AWR; /* 1308h | 08h | APIC Window Register */
__le32 reserved1; /* 130Ch | 0Ch | Reserved */
__le32 IMRx[2]; /* 1310h | 10h | Inbound Message Registers */
__le32 OMRx[2]; /* 1318h | 18h | Outbound Message Registers */
__le32 IDR; /* 1320h | 20h | Inbound Doorbell Register */
__le32 IISR; /* 1324h | 24h | Inbound Interrupt
Status Register */
__le32 IIMR; /* 1328h | 28h | Inbound Interrupt
Mask Register */
__le32 ODR; /* 132Ch | 2Ch | Outbound Doorbell Register */
__le32 OISR; /* 1330h | 30h | Outbound Interrupt
Status Register */
__le32 OIMR; /* 1334h | 34h | Outbound Interrupt
Mask Register */
/* * Must access through ATU Inbound
Translation Window */
};
struct rx_inbound {
__le32 Mailbox[8];
};
#define InboundMailbox0 IndexRegs.Mailbox[0]
#define InboundMailbox1 IndexRegs.Mailbox[1]
#define InboundMailbox2 IndexRegs.Mailbox[2]
#define InboundMailbox3 IndexRegs.Mailbox[3]
#define InboundMailbox4 IndexRegs.Mailbox[4]
#define InboundMailbox5 IndexRegs.Mailbox[5]
#define InboundMailbox6 IndexRegs.Mailbox[6]
#define INBOUNDDOORBELL_0 0x00000001
#define INBOUNDDOORBELL_1 0x00000002
#define INBOUNDDOORBELL_2 0x00000004
#define INBOUNDDOORBELL_3 0x00000008
#define INBOUNDDOORBELL_4 0x00000010
#define INBOUNDDOORBELL_5 0x00000020
#define INBOUNDDOORBELL_6 0x00000040
#define OUTBOUNDDOORBELL_0 0x00000001
#define OUTBOUNDDOORBELL_1 0x00000002
#define OUTBOUNDDOORBELL_2 0x00000004
#define OUTBOUNDDOORBELL_3 0x00000008
#define OUTBOUNDDOORBELL_4 0x00000010
#define InboundDoorbellReg MUnit.IDR
#define OutboundDoorbellReg MUnit.ODR
struct rx_registers {
struct rx_mu_registers MUnit; /* 1300h - 1334h */
__le32 reserved1[6]; /* 1338h - 134ch */
struct rx_inbound IndexRegs;
};
#define rx_readb(AEP, CSR) readb(&((AEP)->regs.rx->CSR))
#define rx_readl(AEP, CSR) readl(&((AEP)->regs.rx->CSR))
#define rx_writeb(AEP, CSR, value) writeb(value, &((AEP)->regs.rx->CSR))
#define rx_writel(AEP, CSR, value) writel(value, &((AEP)->regs.rx->CSR))
/*
* Rkt Message Unit Registers (same as Rx, except a larger reserve region)
*/
#define rkt_mu_registers rx_mu_registers
#define rkt_inbound rx_inbound
struct rkt_registers {
struct rkt_mu_registers MUnit; /* 1300h - 1334h */
__le32 reserved1[1010]; /* 1338h - 22fch */
struct rkt_inbound IndexRegs; /* 2300h - */
};
#define rkt_readb(AEP, CSR) readb(&((AEP)->regs.rkt->CSR))
#define rkt_readl(AEP, CSR) readl(&((AEP)->regs.rkt->CSR))
#define rkt_writeb(AEP, CSR, value) writeb(value, &((AEP)->regs.rkt->CSR))
#define rkt_writel(AEP, CSR, value) writel(value, &((AEP)->regs.rkt->CSR))
struct fib;
typedef void (*fib_callback)(void *ctxt, struct fib *fibctx);
struct aac_fib_context {
s16 type; // used for verification of structure
s16 size;
u32 unique; // unique value representing this context
ulong jiffies; // used for cleanup - dmb changed to ulong
struct list_head next; // used to link context's into a linked list
struct semaphore wait_sem; // this is used to wait for the next fib to arrive.
int wait; // Set to true when thread is in WaitForSingleObject
unsigned long count; // total number of FIBs on FibList
struct list_head fib_list; // this holds fibs and their attachd hw_fibs
};
struct sense_data {
u8 error_code; /* 70h (current errors), 71h(deferred errors) */
u8 valid:1; /* A valid bit of one indicates that the information */
/* field contains valid information as defined in the
* SCSI-2 Standard.
*/
u8 segment_number; /* Only used for COPY, COMPARE, or COPY AND VERIFY Commands */
u8 sense_key:4; /* Sense Key */
u8 reserved:1;
u8 ILI:1; /* Incorrect Length Indicator */
u8 EOM:1; /* End Of Medium - reserved for random access devices */
u8 filemark:1; /* Filemark - reserved for random access devices */
u8 information[4]; /* for direct-access devices, contains the unsigned
* logical block address or residue associated with
* the sense key
*/
u8 add_sense_len; /* number of additional sense bytes to follow this field */
u8 cmnd_info[4]; /* not used */
u8 ASC; /* Additional Sense Code */
u8 ASCQ; /* Additional Sense Code Qualifier */
u8 FRUC; /* Field Replaceable Unit Code - not used */
u8 bit_ptr:3; /* indicates which byte of the CDB or parameter data
* was in error
*/
u8 BPV:1; /* bit pointer valid (BPV): 1- indicates that
* the bit_ptr field has valid value
*/
u8 reserved2:2;
u8 CD:1; /* command data bit: 1- illegal parameter in CDB.
* 0- illegal parameter in data.
*/
u8 SKSV:1;
u8 field_ptr[2]; /* byte of the CDB or parameter data in error */
};
struct fsa_dev_info {
u64 last;
u64 size;
u32 type;
u16 queue_depth;
u8 valid;
u8 ro;
u8 locked;
u8 deleted;
char devname[8];
struct sense_data sense_data;
};
struct fib {
void *next; /* this is used by the allocator */
s16 type;
s16 size;
/*
* The Adapter that this I/O is destined for.
*/
struct aac_dev *dev;
/*
* This is the event the sendfib routine will wait on if the
* caller did not pass one and this is synch io.
*/
struct semaphore event_wait;
spinlock_t event_lock;
u32 done; /* gets set to 1 when fib is complete */
fib_callback callback;
void *callback_data;
u32 flags; // u32 dmb was ulong
/*
* The following is used to put this fib context onto the
* Outstanding I/O queue.
*/
struct list_head queue;
/*
* And for the internal issue/reply queues (we may be able
* to merge these two)
*/
struct list_head fiblink;
void *data;
struct hw_fib *hw_fib; /* Actual shared object */
dma_addr_t hw_fib_pa; /* physical address of hw_fib*/
};
/*
* Adapter Information Block
*
* This is returned by the RequestAdapterInfo block
*/
struct aac_adapter_info
{
__le32 platform;
__le32 cpu;
__le32 subcpu;
__le32 clock;
__le32 execmem;
__le32 buffermem;
__le32 totalmem;
__le32 kernelrev;
__le32 kernelbuild;
__le32 monitorrev;
__le32 monitorbuild;
__le32 hwrev;
__le32 hwbuild;
__le32 biosrev;
__le32 biosbuild;
__le32 cluster;
__le32 clusterchannelmask;
__le32 serial[2];
__le32 battery;
__le32 options;
__le32 OEM;
};
struct aac_supplement_adapter_info
{
u8 AdapterTypeText[17+1];
u8 Pad[2];
__le32 FlashMemoryByteSize;
__le32 FlashImageId;
__le32 MaxNumberPorts;
__le32 Version;
__le32 FeatureBits;
u8 SlotNumber;
u8 ReservedPad0[0];
u8 BuildDate[12];
__le32 CurrentNumberPorts;
__le32 ReservedGrowth[24];
};
#define AAC_FEATURE_FALCON 0x00000010
#define AAC_SIS_VERSION_V3 3
#define AAC_SIS_SLOT_UNKNOWN 0xFF
#define GetBusInfo 0x00000009
struct aac_bus_info {
__le32 Command; /* VM_Ioctl */
__le32 ObjType; /* FT_DRIVE */
__le32 MethodId; /* 1 = SCSI Layer */
__le32 ObjectId; /* Handle */
__le32 CtlCmd; /* GetBusInfo */
};
struct aac_bus_info_response {
__le32 Status; /* ST_OK */
__le32 ObjType;
__le32 MethodId; /* unused */
__le32 ObjectId; /* unused */
__le32 CtlCmd; /* unused */
__le32 ProbeComplete;
__le32 BusCount;
__le32 TargetsPerBus;
u8 InitiatorBusId[10];
u8 BusValid[10];
};
/*
* Battery platforms
*/
#define AAC_BAT_REQ_PRESENT (1)
#define AAC_BAT_REQ_NOTPRESENT (2)
#define AAC_BAT_OPT_PRESENT (3)
#define AAC_BAT_OPT_NOTPRESENT (4)
#define AAC_BAT_NOT_SUPPORTED (5)
/*
* cpu types
*/
#define AAC_CPU_SIMULATOR (1)
#define AAC_CPU_I960 (2)
#define AAC_CPU_STRONGARM (3)
/*
* Supported Options
*/
#define AAC_OPT_SNAPSHOT cpu_to_le32(1)
#define AAC_OPT_CLUSTERS cpu_to_le32(1<<1)
#define AAC_OPT_WRITE_CACHE cpu_to_le32(1<<2)
#define AAC_OPT_64BIT_DATA cpu_to_le32(1<<3)
#define AAC_OPT_HOST_TIME_FIB cpu_to_le32(1<<4)
#define AAC_OPT_RAID50 cpu_to_le32(1<<5)
#define AAC_OPT_4GB_WINDOW cpu_to_le32(1<<6)
#define AAC_OPT_SCSI_UPGRADEABLE cpu_to_le32(1<<7)
#define AAC_OPT_SOFT_ERR_REPORT cpu_to_le32(1<<8)
#define AAC_OPT_SUPPORTED_RECONDITION cpu_to_le32(1<<9)
#define AAC_OPT_SGMAP_HOST64 cpu_to_le32(1<<10)
#define AAC_OPT_ALARM cpu_to_le32(1<<11)
#define AAC_OPT_NONDASD cpu_to_le32(1<<12)
#define AAC_OPT_SCSI_MANAGED cpu_to_le32(1<<13)
#define AAC_OPT_RAID_SCSI_MODE cpu_to_le32(1<<14)
#define AAC_OPT_SUPPLEMENT_ADAPTER_INFO cpu_to_le32(1<<16)
#define AAC_OPT_NEW_COMM cpu_to_le32(1<<17)
#define AAC_OPT_NEW_COMM_64 cpu_to_le32(1<<18)
struct aac_dev
{
struct list_head entry;
const char *name;
int id;
u16 irq_mask;
/*
* negotiated FIB settings
*/
unsigned max_fib_size;
unsigned sg_tablesize;
/*
* Map for 128 fib objects (64k)
*/
dma_addr_t hw_fib_pa;
struct hw_fib *hw_fib_va;
struct hw_fib *aif_base_va;
/*
* Fib Headers
*/
struct fib *fibs;
struct fib *free_fib;
struct fib *timeout_fib;
spinlock_t fib_lock;
struct aac_queue_block *queues;
/*
* The user API will use an IOCTL to register itself to receive
* FIBs from the adapter. The following list is used to keep
* track of all the threads that have requested these FIBs. The
* mutex is used to synchronize access to all data associated
* with the adapter fibs.
*/
struct list_head fib_list;
struct adapter_ops a_ops;
unsigned long fsrev; /* Main driver's revision number */
struct aac_init *init; /* Holds initialization info to communicate with adapter */
dma_addr_t init_pa; /* Holds physical address of the init struct */
struct pci_dev *pdev; /* Our PCI interface */
void * printfbuf; /* pointer to buffer used for printf's from the adapter */
void * comm_addr; /* Base address of Comm area */
dma_addr_t comm_phys; /* Physical Address of Comm area */
size_t comm_size;
struct Scsi_Host *scsi_host_ptr;
int maximum_num_containers;
int maximum_num_physicals;
int maximum_num_channels;
struct fsa_dev_info *fsa_dev;
pid_t thread_pid;
int cardtype;
/*
* The following is the device specific extension.
*/
union
{
struct sa_registers __iomem *sa;
struct rx_registers __iomem *rx;
struct rkt_registers __iomem *rkt;
} regs;
u32 OIMR; /* Mask Register Cache */
/*
* AIF thread states
*/
u32 aif_thread;
struct completion aif_completion;
struct aac_adapter_info adapter_info;
struct aac_supplement_adapter_info supplement_adapter_info;
/* These are in adapter info but they are in the io flow so
* lets break them out so we don't have to do an AND to check them
*/
u8 nondasd_support;
u8 dac_support;
u8 raid_scsi_mode;
/* macro side-effects BEWARE */
# define raw_io_interface \
init->InitStructRevision==cpu_to_le32(ADAPTER_INIT_STRUCT_REVISION_4)
u8 printf_enabled;
};
#define aac_adapter_interrupt(dev) \
(dev)->a_ops.adapter_interrupt(dev)
#define aac_adapter_notify(dev, event) \
(dev)->a_ops.adapter_notify(dev, event)
#define aac_adapter_disable_int(dev) \
(dev)->a_ops.adapter_disable_int(dev)
#define aac_adapter_sync_cmd(dev, command, p1, p2, p3, p4, p5, p6, status, r1, r2, r3, r4) \
(dev)->a_ops.adapter_sync_cmd(dev, command, p1, p2, p3, p4, p5, p6, status, r1, r2, r3, r4)
#define aac_adapter_check_health(dev) \
(dev)->a_ops.adapter_check_health(dev)
#define FIB_CONTEXT_FLAG_TIMED_OUT (0x00000001)
/*
* Define the command values
*/
#define Null 0
#define GetAttributes 1
#define SetAttributes 2
#define Lookup 3
#define ReadLink 4
#define Read 5
#define Write 6
#define Create 7
#define MakeDirectory 8
#define SymbolicLink 9
#define MakeNode 10
#define Removex 11
#define RemoveDirectoryx 12
#define Rename 13
#define Link 14
#define ReadDirectory 15
#define ReadDirectoryPlus 16
#define FileSystemStatus 17
#define FileSystemInfo 18
#define PathConfigure 19
#define Commit 20
#define Mount 21
#define UnMount 22
#define Newfs 23
#define FsCheck 24
#define FsSync 25
#define SimReadWrite 26
#define SetFileSystemStatus 27
#define BlockRead 28
#define BlockWrite 29
#define NvramIoctl 30
#define FsSyncWait 31
#define ClearArchiveBit 32
#define SetAcl 33
#define GetAcl 34
#define AssignAcl 35
#define FaultInsertion 36 /* Fault Insertion Command */
#define CrazyCache 37 /* Crazycache */
#define MAX_FSACOMMAND_NUM 38
/*
* Define the status returns. These are very unixlike although
* most are not in fact used
*/
#define ST_OK 0
#define ST_PERM 1
#define ST_NOENT 2
#define ST_IO 5
#define ST_NXIO 6
#define ST_E2BIG 7
#define ST_ACCES 13
#define ST_EXIST 17
#define ST_XDEV 18
#define ST_NODEV 19
#define ST_NOTDIR 20
#define ST_ISDIR 21
#define ST_INVAL 22
#define ST_FBIG 27
#define ST_NOSPC 28
#define ST_ROFS 30
#define ST_MLINK 31
#define ST_WOULDBLOCK 35
#define ST_NAMETOOLONG 63
#define ST_NOTEMPTY 66
#define ST_DQUOT 69
#define ST_STALE 70
#define ST_REMOTE 71
#define ST_BADHANDLE 10001
#define ST_NOT_SYNC 10002
#define ST_BAD_COOKIE 10003
#define ST_NOTSUPP 10004
#define ST_TOOSMALL 10005
#define ST_SERVERFAULT 10006
#define ST_BADTYPE 10007
#define ST_JUKEBOX 10008
#define ST_NOTMOUNTED 10009
#define ST_MAINTMODE 10010
#define ST_STALEACL 10011
/*
* On writes how does the client want the data written.
*/
#define CACHE_CSTABLE 1
#define CACHE_UNSTABLE 2
/*
* Lets the client know at which level the data was commited on
* a write request
*/
#define CMFILE_SYNCH_NVRAM 1
#define CMDATA_SYNCH_NVRAM 2
#define CMFILE_SYNCH 3
#define CMDATA_SYNCH 4
#define CMUNSTABLE 5
struct aac_read
{
__le32 command;
__le32 cid;
__le32 block;
__le32 count;
struct sgmap sg; // Must be last in struct because it is variable
};
struct aac_read64
{
__le32 command;
__le16 cid;
__le16 sector_count;
__le32 block;
__le16 pad;
__le16 flags;
struct sgmap64 sg; // Must be last in struct because it is variable
};
struct aac_read_reply
{
__le32 status;
__le32 count;
};
struct aac_write
{
__le32 command;
__le32 cid;
__le32 block;
__le32 count;
__le32 stable; // Not used
struct sgmap sg; // Must be last in struct because it is variable
};
struct aac_write64
{
__le32 command;
__le16 cid;
__le16 sector_count;
__le32 block;
__le16 pad;
__le16 flags;
struct sgmap64 sg; // Must be last in struct because it is variable
};
struct aac_write_reply
{
__le32 status;
__le32 count;
__le32 committed;
};
struct aac_raw_io
{
__le32 block[2];
__le32 count;
__le16 cid;
__le16 flags; /* 00 W, 01 R */
__le16 bpTotal; /* reserved for F/W use */
__le16 bpComplete; /* reserved for F/W use */
struct sgmapraw sg;
};
#define CT_FLUSH_CACHE 129
struct aac_synchronize {
__le32 command; /* VM_ContainerConfig */
__le32 type; /* CT_FLUSH_CACHE */
__le32 cid;
__le32 parm1;
__le32 parm2;
__le32 parm3;
__le32 parm4;
__le32 count; /* sizeof(((struct aac_synchronize_reply *)NULL)->data) */
};
struct aac_synchronize_reply {
__le32 dummy0;
__le32 dummy1;
__le32 status; /* CT_OK */
__le32 parm1;
__le32 parm2;
__le32 parm3;
__le32 parm4;
__le32 parm5;
u8 data[16];
};
struct aac_srb
{
__le32 function;
__le32 channel;
__le32 id;
__le32 lun;
__le32 timeout;
__le32 flags;
__le32 count; // Data xfer size
__le32 retry_limit;
__le32 cdb_size;
u8 cdb[16];
struct sgmap sg;
};
/*
* This and associated data structs are used by the
* ioctl caller and are in cpu order.
*/
struct user_aac_srb
{
u32 function;
u32 channel;
u32 id;
u32 lun;
u32 timeout;
u32 flags;
u32 count; // Data xfer size
u32 retry_limit;
u32 cdb_size;
u8 cdb[16];
struct user_sgmap sg;
};
#define AAC_SENSE_BUFFERSIZE 30
struct aac_srb_reply
{
__le32 status;
__le32 srb_status;
__le32 scsi_status;
__le32 data_xfer_length;
__le32 sense_data_size;
u8 sense_data[AAC_SENSE_BUFFERSIZE]; // Can this be SCSI_SENSE_BUFFERSIZE
};
/*
* SRB Flags
*/
#define SRB_NoDataXfer 0x0000
#define SRB_DisableDisconnect 0x0004
#define SRB_DisableSynchTransfer 0x0008
#define SRB_BypassFrozenQueue 0x0010
#define SRB_DisableAutosense 0x0020
#define SRB_DataIn 0x0040
#define SRB_DataOut 0x0080
/*
* SRB Functions - set in aac_srb->function
*/
#define SRBF_ExecuteScsi 0x0000
#define SRBF_ClaimDevice 0x0001
#define SRBF_IO_Control 0x0002
#define SRBF_ReceiveEvent 0x0003
#define SRBF_ReleaseQueue 0x0004
#define SRBF_AttachDevice 0x0005
#define SRBF_ReleaseDevice 0x0006
#define SRBF_Shutdown 0x0007
#define SRBF_Flush 0x0008
#define SRBF_AbortCommand 0x0010
#define SRBF_ReleaseRecovery 0x0011
#define SRBF_ResetBus 0x0012
#define SRBF_ResetDevice 0x0013
#define SRBF_TerminateIO 0x0014
#define SRBF_FlushQueue 0x0015
#define SRBF_RemoveDevice 0x0016
#define SRBF_DomainValidation 0x0017
/*
* SRB SCSI Status - set in aac_srb->scsi_status
*/
#define SRB_STATUS_PENDING 0x00
#define SRB_STATUS_SUCCESS 0x01
#define SRB_STATUS_ABORTED 0x02
#define SRB_STATUS_ABORT_FAILED 0x03
#define SRB_STATUS_ERROR 0x04
#define SRB_STATUS_BUSY 0x05
#define SRB_STATUS_INVALID_REQUEST 0x06
#define SRB_STATUS_INVALID_PATH_ID 0x07
#define SRB_STATUS_NO_DEVICE 0x08
#define SRB_STATUS_TIMEOUT 0x09
#define SRB_STATUS_SELECTION_TIMEOUT 0x0A
#define SRB_STATUS_COMMAND_TIMEOUT 0x0B
#define SRB_STATUS_MESSAGE_REJECTED 0x0D
#define SRB_STATUS_BUS_RESET 0x0E
#define SRB_STATUS_PARITY_ERROR 0x0F
#define SRB_STATUS_REQUEST_SENSE_FAILED 0x10
#define SRB_STATUS_NO_HBA 0x11
#define SRB_STATUS_DATA_OVERRUN 0x12
#define SRB_STATUS_UNEXPECTED_BUS_FREE 0x13
#define SRB_STATUS_PHASE_SEQUENCE_FAILURE 0x14
#define SRB_STATUS_BAD_SRB_BLOCK_LENGTH 0x15
#define SRB_STATUS_REQUEST_FLUSHED 0x16
#define SRB_STATUS_DELAYED_RETRY 0x17
#define SRB_STATUS_INVALID_LUN 0x20
#define SRB_STATUS_INVALID_TARGET_ID 0x21
#define SRB_STATUS_BAD_FUNCTION 0x22
#define SRB_STATUS_ERROR_RECOVERY 0x23
#define SRB_STATUS_NOT_STARTED 0x24
#define SRB_STATUS_NOT_IN_USE 0x30
#define SRB_STATUS_FORCE_ABORT 0x31
#define SRB_STATUS_DOMAIN_VALIDATION_FAIL 0x32
/*
* Object-Server / Volume-Manager Dispatch Classes
*/
#define VM_Null 0
#define VM_NameServe 1
#define VM_ContainerConfig 2
#define VM_Ioctl 3
#define VM_FilesystemIoctl 4
#define VM_CloseAll 5
#define VM_CtBlockRead 6
#define VM_CtBlockWrite 7
#define VM_SliceBlockRead 8 /* raw access to configured "storage objects" */
#define VM_SliceBlockWrite 9
#define VM_DriveBlockRead 10 /* raw access to physical devices */
#define VM_DriveBlockWrite 11
#define VM_EnclosureMgt 12 /* enclosure management */
#define VM_Unused 13 /* used to be diskset management */
#define VM_CtBlockVerify 14
#define VM_CtPerf 15 /* performance test */
#define VM_CtBlockRead64 16
#define VM_CtBlockWrite64 17
#define VM_CtBlockVerify64 18
#define VM_CtHostRead64 19
#define VM_CtHostWrite64 20
#define MAX_VMCOMMAND_NUM 21 /* used for sizing stats array - leave last */
/*
* Descriptive information (eg, vital stats)
* that a content manager might report. The
* FileArray filesystem component is one example
* of a content manager. Raw mode might be
* another.
*/
struct aac_fsinfo {
__le32 fsTotalSize; /* Consumed by fs, incl. metadata */
__le32 fsBlockSize;
__le32 fsFragSize;
__le32 fsMaxExtendSize;
__le32 fsSpaceUnits;
__le32 fsMaxNumFiles;
__le32 fsNumFreeFiles;
__le32 fsInodeDensity;
}; /* valid iff ObjType == FT_FILESYS && !(ContentState & FSCS_NOTCLEAN) */
union aac_contentinfo {
struct aac_fsinfo filesys; /* valid iff ObjType == FT_FILESYS && !(ContentState & FSCS_NOTCLEAN) */
};
/*
* Query for Container Configuration Status
*/
#define CT_GET_CONFIG_STATUS 147
struct aac_get_config_status {
__le32 command; /* VM_ContainerConfig */
__le32 type; /* CT_GET_CONFIG_STATUS */
__le32 parm1;
__le32 parm2;
__le32 parm3;
__le32 parm4;
__le32 parm5;
__le32 count; /* sizeof(((struct aac_get_config_status_resp *)NULL)->data) */
};
#define CFACT_CONTINUE 0
#define CFACT_PAUSE 1
#define CFACT_ABORT 2
struct aac_get_config_status_resp {
__le32 response; /* ST_OK */
__le32 dummy0;
__le32 status; /* CT_OK */
__le32 parm1;
__le32 parm2;
__le32 parm3;
__le32 parm4;
__le32 parm5;
struct {
__le32 action; /* CFACT_CONTINUE, CFACT_PAUSE or CFACT_ABORT */
__le16 flags;
__le16 count;
} data;
};
/*
* Accept the configuration as-is
*/
#define CT_COMMIT_CONFIG 152
struct aac_commit_config {
__le32 command; /* VM_ContainerConfig */
__le32 type; /* CT_COMMIT_CONFIG */
};
/*
* Query for Container Configuration Status
*/
#define CT_GET_CONTAINER_COUNT 4
struct aac_get_container_count {
__le32 command; /* VM_ContainerConfig */
__le32 type; /* CT_GET_CONTAINER_COUNT */
};
struct aac_get_container_count_resp {
__le32 response; /* ST_OK */
__le32 dummy0;
__le32 MaxContainers;
__le32 ContainerSwitchEntries;
__le32 MaxPartitions;
};
/*
* Query for "mountable" objects, ie, objects that are typically
* associated with a drive letter on the client (host) side.
*/
struct aac_mntent {
__le32 oid;
u8 name[16]; /* if applicable */
struct creation_info create_info; /* if applicable */
__le32 capacity;
__le32 vol; /* substrate structure */
__le32 obj; /* FT_FILESYS,
FT_DATABASE, etc. */
__le32 state; /* unready for mounting,
readonly, etc. */
union aac_contentinfo fileinfo; /* Info specific to content
manager (eg, filesystem) */
__le32 altoid; /* != oid <==> snapshot or
broken mirror exists */
};
#define FSCS_NOTCLEAN 0x0001 /* fsck is neccessary before mounting */
#define FSCS_READONLY 0x0002 /* possible result of broken mirror */
#define FSCS_HIDDEN 0x0004 /* should be ignored - set during a clear */
struct aac_query_mount {
__le32 command;
__le32 type;
__le32 count;
};
struct aac_mount {
__le32 status;
__le32 type; /* should be same as that requested */
__le32 count;
struct aac_mntent mnt[1];
};
#define CT_READ_NAME 130
struct aac_get_name {
__le32 command; /* VM_ContainerConfig */
__le32 type; /* CT_READ_NAME */
__le32 cid;
__le32 parm1;
__le32 parm2;
__le32 parm3;
__le32 parm4;
__le32 count; /* sizeof(((struct aac_get_name_resp *)NULL)->data) */
};
#define CT_OK 218
struct aac_get_name_resp {
__le32 dummy0;
__le32 dummy1;
__le32 status; /* CT_OK */
__le32 parm1;
__le32 parm2;
__le32 parm3;
__le32 parm4;
__le32 parm5;
u8 data[16];
};
/*
* The following command is sent to shut down each container.
*/
struct aac_close {
__le32 command;
__le32 cid;
};
struct aac_query_disk
{
s32 cnum;
s32 bus;
s32 id;
s32 lun;
u32 valid;
u32 locked;
u32 deleted;
s32 instance;
s8 name[10];
u32 unmapped;
};
struct aac_delete_disk {
u32 disknum;
u32 cnum;
};
struct fib_ioctl
{
u32 fibctx;
s32 wait;
char __user *fib;
};
struct revision
{
__le32 compat;
__le32 version;
__le32 build;
};
/*
* Ugly - non Linux like ioctl coding for back compat.
*/
#define CTL_CODE(function, method) ( \
(4<< 16) | ((function) << 2) | (method) \
)
/*
* Define the method codes for how buffers are passed for I/O and FS
* controls
*/
#define METHOD_BUFFERED 0
#define METHOD_NEITHER 3
/*
* Filesystem ioctls
*/
#define FSACTL_SENDFIB CTL_CODE(2050, METHOD_BUFFERED)
#define FSACTL_SEND_RAW_SRB CTL_CODE(2067, METHOD_BUFFERED)
#define FSACTL_DELETE_DISK 0x163
#define FSACTL_QUERY_DISK 0x173
#define FSACTL_OPEN_GET_ADAPTER_FIB CTL_CODE(2100, METHOD_BUFFERED)
#define FSACTL_GET_NEXT_ADAPTER_FIB CTL_CODE(2101, METHOD_BUFFERED)
#define FSACTL_CLOSE_GET_ADAPTER_FIB CTL_CODE(2102, METHOD_BUFFERED)
#define FSACTL_MINIPORT_REV_CHECK CTL_CODE(2107, METHOD_BUFFERED)
#define FSACTL_GET_PCI_INFO CTL_CODE(2119, METHOD_BUFFERED)
#define FSACTL_FORCE_DELETE_DISK CTL_CODE(2120, METHOD_NEITHER)
#define FSACTL_GET_CONTAINERS 2131
#define FSACTL_SEND_LARGE_FIB CTL_CODE(2138, METHOD_BUFFERED)
struct aac_common
{
/*
* If this value is set to 1 then interrupt moderation will occur
* in the base commuication support.
*/
u32 irq_mod;
u32 peak_fibs;
u32 zero_fibs;
u32 fib_timeouts;
/*
* Statistical counters in debug mode
*/
#ifdef DBG
u32 FibsSent;
u32 FibRecved;
u32 NoResponseSent;
u32 NoResponseRecved;
u32 AsyncSent;
u32 AsyncRecved;
u32 NormalSent;
u32 NormalRecved;
#endif
};
extern struct aac_common aac_config;
/*
* The following macro is used when sending and receiving FIBs. It is
* only used for debugging.
*/
#ifdef DBG
#define FIB_COUNTER_INCREMENT(counter) (counter)++
#else
#define FIB_COUNTER_INCREMENT(counter)
#endif
/*
* Adapter direct commands
* Monitor/Kernel API
*/
#define BREAKPOINT_REQUEST 0x00000004
#define INIT_STRUCT_BASE_ADDRESS 0x00000005
#define READ_PERMANENT_PARAMETERS 0x0000000a
#define WRITE_PERMANENT_PARAMETERS 0x0000000b
#define HOST_CRASHING 0x0000000d
#define SEND_SYNCHRONOUS_FIB 0x0000000c
#define COMMAND_POST_RESULTS 0x00000014
#define GET_ADAPTER_PROPERTIES 0x00000019
#define GET_DRIVER_BUFFER_PROPERTIES 0x00000023
#define RCV_TEMP_READINGS 0x00000025
#define GET_COMM_PREFERRED_SETTINGS 0x00000026
#define IOP_RESET 0x00001000
#define RE_INIT_ADAPTER 0x000000ee
/*
* Adapter Status Register
*
* Phase Staus mailbox is 32bits:
* <31:16> = Phase Status
* <15:0> = Phase
*
* The adapter reports is present state through the phase. Only
* a single phase should be ever be set. Each phase can have multiple
* phase status bits to provide more detailed information about the
* state of the board. Care should be taken to ensure that any phase
* status bits that are set when changing the phase are also valid
* for the new phase or be cleared out. Adapter software (monitor,
* iflash, kernel) is responsible for properly maintining the phase
* status mailbox when it is running.
*
* MONKER_API Phases
*
* Phases are bit oriented. It is NOT valid to have multiple bits set
*/
#define SELF_TEST_FAILED 0x00000004
#define MONITOR_PANIC 0x00000020
#define KERNEL_UP_AND_RUNNING 0x00000080
#define KERNEL_PANIC 0x00000100
/*
* Doorbell bit defines
*/
#define DoorBellSyncCmdAvailable (1<<0) /* Host -> Adapter */
#define DoorBellPrintfDone (1<<5) /* Host -> Adapter */
#define DoorBellAdapterNormCmdReady (1<<1) /* Adapter -> Host */
#define DoorBellAdapterNormRespReady (1<<2) /* Adapter -> Host */
#define DoorBellAdapterNormCmdNotFull (1<<3) /* Adapter -> Host */
#define DoorBellAdapterNormRespNotFull (1<<4) /* Adapter -> Host */
#define DoorBellPrintfReady (1<<5) /* Adapter -> Host */
/*
* For FIB communication, we need all of the following things
* to send back to the user.
*/
#define AifCmdEventNotify 1 /* Notify of event */
#define AifEnConfigChange 3 /* Adapter configuration change */
#define AifEnContainerChange 4 /* Container configuration change */
#define AifEnDeviceFailure 5 /* SCSI device failed */
#define AifEnAddContainer 15 /* A new array was created */
#define AifEnDeleteContainer 16 /* A container was deleted */
#define AifEnExpEvent 23 /* Firmware Event Log */
#define AifExeFirmwarePanic 3 /* Firmware Event Panic */
#define AifHighPriority 3 /* Highest Priority Event */
#define AifCmdJobProgress 2 /* Progress report */
#define AifJobCtrZero 101 /* Array Zero progress */
#define AifJobStsSuccess 1 /* Job completes */
#define AifCmdAPIReport 3 /* Report from other user of API */
#define AifCmdDriverNotify 4 /* Notify host driver of event */
#define AifDenMorphComplete 200 /* A morph operation completed */
#define AifDenVolumeExtendComplete 201 /* A volume extend completed */
#define AifReqJobList 100 /* Gets back complete job list */
#define AifReqJobsForCtr 101 /* Gets back jobs for specific container */
#define AifReqJobsForScsi 102 /* Gets back jobs for specific SCSI device */
#define AifReqJobReport 103 /* Gets back a specific job report or list of them */
#define AifReqTerminateJob 104 /* Terminates job */
#define AifReqSuspendJob 105 /* Suspends a job */
#define AifReqResumeJob 106 /* Resumes a job */
#define AifReqSendAPIReport 107 /* API generic report requests */
#define AifReqAPIJobStart 108 /* Start a job from the API */
#define AifReqAPIJobUpdate 109 /* Update a job report from the API */
#define AifReqAPIJobFinish 110 /* Finish a job from the API */
/*
* Adapter Initiated FIB command structures. Start with the adapter
* initiated FIBs that really come from the adapter, and get responded
* to by the host.
*/
struct aac_aifcmd {
__le32 command; /* Tell host what type of notify this is */
__le32 seqnum; /* To allow ordering of reports (if necessary) */
u8 data[1]; /* Undefined length (from kernel viewpoint) */
};
/**
* Convert capacity to cylinders
* accounting for the fact capacity could be a 64 bit value
*
*/
static inline u32 cap_to_cyls(sector_t capacity, u32 divisor)
{
sector_div(capacity, divisor);
return (u32)capacity;
}
struct scsi_cmnd;
const char *aac_driverinfo(struct Scsi_Host *);
struct fib *fib_alloc(struct aac_dev *dev);
int fib_setup(struct aac_dev *dev);
void fib_map_free(struct aac_dev *dev);
void fib_free(struct fib * context);
void fib_init(struct fib * context);
void aac_printf(struct aac_dev *dev, u32 val);
int fib_send(u16 command, struct fib * context, unsigned long size, int priority, int wait, int reply, fib_callback callback, void *ctxt);
int aac_consumer_get(struct aac_dev * dev, struct aac_queue * q, struct aac_entry **entry);
void aac_consumer_free(struct aac_dev * dev, struct aac_queue * q, u32 qnum);
int fib_complete(struct fib * context);
#define fib_data(fibctx) ((void *)(fibctx)->hw_fib->data)
struct aac_dev *aac_init_adapter(struct aac_dev *dev);
int aac_get_config_status(struct aac_dev *dev);
int aac_get_containers(struct aac_dev *dev);
int aac_scsi_cmd(struct scsi_cmnd *cmd);
int aac_dev_ioctl(struct aac_dev *dev, int cmd, void __user *arg);
int aac_do_ioctl(struct aac_dev * dev, int cmd, void __user *arg);
int aac_rx_init(struct aac_dev *dev);
int aac_rkt_init(struct aac_dev *dev);
int aac_sa_init(struct aac_dev *dev);
unsigned int aac_response_normal(struct aac_queue * q);
unsigned int aac_command_normal(struct aac_queue * q);
int aac_command_thread(struct aac_dev * dev);
int aac_close_fib_context(struct aac_dev * dev, struct aac_fib_context *fibctx);
int fib_adapter_complete(struct fib * fibptr, unsigned short size);
struct aac_driver_ident* aac_get_driver_ident(int devtype);
int aac_get_adapter_info(struct aac_dev* dev);
int aac_send_shutdown(struct aac_dev *dev);
extern int numacb;
extern int acbsize;
extern char aac_driver_version[];