freebsd-dev/sys/dev/isp/ispvar.h

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1999-08-28 01:08:13 +00:00
/* $FreeBSD$ */
/*
* Soft Definitions for for Qlogic ISP SCSI adapters.
*
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* Copyright (c) 1997, 1998, 1999, 2000 by Matthew Jacob
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice immediately at the beginning of the file, without modification,
* this list of conditions, and the following disclaimer.
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* 2. The name of the author may not be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
*/
#ifndef _ISPVAR_H
#define _ISPVAR_H
#if defined(__NetBSD__) || defined(__OpenBSD__)
#include <dev/ic/ispmbox.h>
#ifdef ISP_TARGET_MODE
#include <dev/ic/isp_target.h>
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#include <dev/ic/isp_tpublic.h>
#endif
#endif
#ifdef __FreeBSD__
#include <dev/isp/ispmbox.h>
#ifdef ISP_TARGET_MODE
#include <dev/isp/isp_target.h>
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#include <dev/isp/isp_tpublic.h>
#endif
#endif
#ifdef __linux__
#include "ispmbox.h"
#ifdef ISP_TARGET_MODE
#include "isp_target.h"
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#include "isp_tpublic.h"
#endif
#endif
#define ISP_CORE_VERSION_MAJOR 2
#define ISP_CORE_VERSION_MINOR 4
/*
* Vector for bus specific code to provide specific services.
*/
struct ispsoftc;
struct ispmdvec {
int (*dv_rd_isr)
(struct ispsoftc *, u_int16_t *, u_int16_t *, u_int16_t *);
u_int16_t (*dv_rd_reg) (struct ispsoftc *, int);
void (*dv_wr_reg) (struct ispsoftc *, int, u_int16_t);
int (*dv_mbxdma) (struct ispsoftc *);
int (*dv_dmaset) (struct ispsoftc *,
XS_T *, ispreq_t *, u_int16_t *, u_int16_t);
void (*dv_dmaclr)
(struct ispsoftc *, XS_T *, u_int16_t);
void (*dv_reset0) (struct ispsoftc *);
void (*dv_reset1) (struct ispsoftc *);
void (*dv_dregs) (struct ispsoftc *, const char *);
const u_int16_t *dv_ispfw; /* ptr to f/w */
u_int16_t dv_conf1;
u_int16_t dv_clock; /* clock frequency */
};
/*
* Overall parameters
*/
#define MAX_TARGETS 16
#define MAX_FC_TARG 256
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#define ISP_MAX_TARGETS(isp) (IS_FC(isp)? MAX_FC_TARG : MAX_TARGETS)
#define ISP_MAX_LUNS(isp) (isp)->isp_maxluns
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/*
* 'Types'
*/
#ifndef ISP_DMA_ADDR_T
#define ISP_DMA_ADDR_T u_int32_t
#endif
/*
* Macros to access ISP registers through bus specific layers-
* mostly wrappers to vector through the mdvec structure.
*/
#define ISP_READ_ISR(isp, isrp, semap, mbox0p) \
(*(isp)->isp_mdvec->dv_rd_isr)(isp, isrp, semap, mbox0p)
#define ISP_READ(isp, reg) \
(*(isp)->isp_mdvec->dv_rd_reg)((isp), (reg))
#define ISP_WRITE(isp, reg, val) \
(*(isp)->isp_mdvec->dv_wr_reg)((isp), (reg), (val))
#define ISP_MBOXDMASETUP(isp) \
(*(isp)->isp_mdvec->dv_mbxdma)((isp))
#define ISP_DMASETUP(isp, xs, req, iptrp, optr) \
(*(isp)->isp_mdvec->dv_dmaset)((isp), (xs), (req), (iptrp), (optr))
#define ISP_DMAFREE(isp, xs, hndl) \
if ((isp)->isp_mdvec->dv_dmaclr) \
(*(isp)->isp_mdvec->dv_dmaclr)((isp), (xs), (hndl))
#define ISP_RESET0(isp) \
if ((isp)->isp_mdvec->dv_reset0) (*(isp)->isp_mdvec->dv_reset0)((isp))
#define ISP_RESET1(isp) \
if ((isp)->isp_mdvec->dv_reset1) (*(isp)->isp_mdvec->dv_reset1)((isp))
#define ISP_DUMPREGS(isp, m) \
if ((isp)->isp_mdvec->dv_dregs) (*(isp)->isp_mdvec->dv_dregs)((isp),(m))
#define ISP_SETBITS(isp, reg, val) \
(*(isp)->isp_mdvec->dv_wr_reg)((isp), (reg), ISP_READ((isp), (reg)) | (val))
#define ISP_CLRBITS(isp, reg, val) \
(*(isp)->isp_mdvec->dv_wr_reg)((isp), (reg), ISP_READ((isp), (reg)) & ~(val))
/*
* The MEMORYBARRIER macro is defined per platform (to provide synchronization
* on Request and Response Queues, Scratch DMA areas, and Registers)
*
* Defined Memory Barrier Synchronization Types
*/
#define SYNC_REQUEST 0 /* request queue synchronization */
#define SYNC_RESULT 1 /* result queue synchronization */
#define SYNC_SFORDEV 2 /* scratch, sync for ISP */
#define SYNC_SFORCPU 3 /* scratch, sync for CPU */
#define SYNC_REG 4 /* for registers */
/*
* Request/Response Queue defines and macros.
* The maximum is defined per platform (and can be based on board type).
*/
/* This is the size of a queue entry (request and response) */
#define QENTRY_LEN 64
/* Both request and result queue length must be a power of two */
#define RQUEST_QUEUE_LEN(x) MAXISPREQUEST(x)
#define RESULT_QUEUE_LEN(x) \
(((MAXISPREQUEST(x) >> 2) < 64)? 64 : MAXISPREQUEST(x) >> 2)
#define ISP_QUEUE_ENTRY(q, idx) ((q) + ((idx) * QENTRY_LEN))
#define ISP_QUEUE_SIZE(n) ((n) * QENTRY_LEN)
#define ISP_NXT_QENTRY(idx, qlen) (((idx) + 1) & ((qlen)-1))
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#define ISP_QFREE(in, out, qlen) \
((in == out)? (qlen - 1) : ((in > out)? \
((qlen - 1) - (in - out)) : (out - in - 1)))
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#define ISP_QAVAIL(isp) \
ISP_QFREE(isp->isp_reqidx, isp->isp_reqodx, RQUEST_QUEUE_LEN(isp))
#define ISP_ADD_REQUEST(isp, iptr) \
MEMORYBARRIER(isp, SYNC_REQUEST, iptr, QENTRY_LEN); \
WRITE_REQUEST_QUEUE_IN_POINTER(isp, iptr); \
isp->isp_reqidx = iptr
/*
* SCSI Specific Host Adapter Parameters- per bus, per target
*/
typedef struct {
u_int isp_gotdparms : 1,
isp_req_ack_active_neg : 1,
isp_data_line_active_neg: 1,
isp_cmd_dma_burst_enable: 1,
isp_data_dma_burst_enabl: 1,
isp_fifo_threshold : 3,
isp_ultramode : 1,
isp_diffmode : 1,
isp_lvdmode : 1,
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isp_fast_mttr : 1, /* fast sram */
isp_initiator_id : 4,
isp_async_data_setup : 4;
u_int16_t isp_selection_timeout;
u_int16_t isp_max_queue_depth;
u_int8_t isp_tag_aging;
u_int8_t isp_bus_reset_delay;
u_int8_t isp_retry_count;
u_int8_t isp_retry_delay;
struct {
u_int32_t
exc_throttle : 8,
: 1,
dev_enable : 1, /* ignored */
dev_update : 1,
dev_refresh : 1,
actv_offset : 4,
goal_offset : 4,
nvrm_offset : 4;
u_int8_t actv_period; /* current sync period */
u_int8_t goal_period; /* goal sync period */
u_int8_t nvrm_period; /* nvram sync period */
u_int16_t actv_flags; /* current device flags */
u_int16_t goal_flags; /* goal device flags */
u_int16_t nvrm_flags; /* nvram device flags */
} isp_devparam[MAX_TARGETS];
} sdparam;
/*
* Device Flags
*/
#define DPARM_DISC 0x8000
#define DPARM_PARITY 0x4000
#define DPARM_WIDE 0x2000
#define DPARM_SYNC 0x1000
#define DPARM_TQING 0x0800
#define DPARM_ARQ 0x0400
#define DPARM_QFRZ 0x0200
#define DPARM_RENEG 0x0100
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#define DPARM_NARROW 0x0080
#define DPARM_ASYNC 0x0040
#define DPARM_PPR 0x0020
#define DPARM_DEFAULT (0xFF00 & ~DPARM_QFRZ)
#define DPARM_SAFE_DFLT (DPARM_DEFAULT & ~(DPARM_WIDE|DPARM_SYNC|DPARM_TQING))
/* technically, not really correct, as they need to be rated based upon clock */
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#define ISP_80M_SYNCPARMS 0x0c09
#define ISP_40M_SYNCPARMS 0x0c0a
#define ISP_20M_SYNCPARMS 0x0c0c
#define ISP_20M_SYNCPARMS_1040 0x080c
#define ISP_10M_SYNCPARMS 0x0c19
#define ISP_08M_SYNCPARMS 0x0c25
#define ISP_05M_SYNCPARMS 0x0c32
#define ISP_04M_SYNCPARMS 0x0c41
/*
* Fibre Channel Specifics
*/
#define FL_PORT_ID 0x7e /* FL_Port Special ID */
#define FC_PORT_ID 0x7f /* Fabric Controller Special ID */
#define FC_SNS_ID 0x80 /* SNS Server Special ID */
typedef struct {
u_int32_t isp_fwoptions : 16,
: 2,
isp_iid_set : 1,
loop_seen_once : 1,
isp_loopstate : 4, /* Current Loop State */
isp_fwstate : 3, /* ISP F/W state */
isp_gotdparms : 1,
isp_topo : 3,
isp_onfabric : 1;
u_int8_t isp_iid; /* 'initiator' id */
u_int8_t isp_loopid; /* hard loop id */
u_int8_t isp_alpa; /* ALPA */
u_int32_t isp_portid;
volatile u_int16_t isp_lipseq; /* LIP sequence # */
u_int16_t isp_fwattr; /* firmware attributes */
u_int8_t isp_execthrottle;
u_int8_t isp_retry_delay;
u_int8_t isp_retry_count;
u_int8_t isp_reserved;
u_int16_t isp_maxalloc;
u_int16_t isp_maxfrmlen;
u_int64_t isp_nodewwn;
u_int64_t isp_portwwn;
/*
* Port Data Base. This is indexed by 'target', which is invariate.
* However, elements within can move around due to loop changes,
* so the actual loop ID passed to the F/W is in this structure.
* The first time the loop is seen up, loopid will match the index
* (except for fabric nodes which are above mapped above FC_SNS_ID
* and are completely virtual), but subsequent LIPs can cause things
* to move around.
*/
struct lportdb {
u_int
loopid : 8,
: 1,
force_logout : 1,
was_fabric_dev : 1,
fabric_dev : 1,
loggedin : 1,
roles : 2,
valid : 1;
u_int32_t portid;
u_int64_t node_wwn;
u_int64_t port_wwn;
} portdb[MAX_FC_TARG], tport[FC_PORT_ID];
/*
* Scratch DMA mapped in area to fetch Port Database stuff, etc.
*/
caddr_t isp_scratch;
ISP_DMA_ADDR_T isp_scdma;
} fcparam;
#define FW_CONFIG_WAIT 0
#define FW_WAIT_AL_PA 1
#define FW_WAIT_LOGIN 2
#define FW_READY 3
#define FW_LOSS_OF_SYNC 4
#define FW_ERROR 5
#define FW_REINIT 6
#define FW_NON_PART 7
#define LOOP_NIL 0
#define LOOP_LIP_RCVD 1
#define LOOP_PDB_RCVD 2
#define LOOP_SCANNING_FABRIC 3
#define LOOP_FSCAN_DONE 4
#define LOOP_SCANNING_LOOP 5
#define LOOP_LSCAN_DONE 6
#define LOOP_SYNCING_PDB 7
#define LOOP_READY 8
#define TOPO_NL_PORT 0
#define TOPO_FL_PORT 1
#define TOPO_N_PORT 2
#define TOPO_F_PORT 3
#define TOPO_PTP_STUB 4
/*
* Soft Structure per host adapter
*/
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typedef struct ispsoftc {
/*
* Platform (OS) specific data
*/
struct isposinfo isp_osinfo;
/*
* Pointer to bus specific functions and data
*/
struct ispmdvec * isp_mdvec;
/*
* (Mostly) nonvolatile state. Board specific parameters
* may contain some volatile state (e.g., current loop state).
*/
void * isp_param; /* type specific */
u_int16_t isp_fwrev[3]; /* Loaded F/W revision */
u_int16_t isp_romfw_rev[3]; /* PROM F/W revision */
u_int16_t isp_maxcmds; /* max possible I/O cmds */
u_int8_t isp_type; /* HBA Chip Type */
u_int8_t isp_revision; /* HBA Chip H/W Revision */
u_int32_t isp_maxluns; /* maximum luns supported */
u_int32_t isp_clock : 8, /* input clock */
: 6,
isp_role : 2,
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: 1,
isp_touched : 1, /* board ever seen? */
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isp_bustype : 1, /* SBus or PCI */
isp_loaded_fw : 1, /* loaded firmware */
isp_dblev : 12; /* debug log mask */
u_int32_t isp_confopts; /* config options */
u_int16_t isp_rqstinrp; /* register for REQINP */
u_int16_t isp_rqstoutrp; /* register for REQOUTP */
u_int16_t isp_respinrp; /* register for RESINP */
u_int16_t isp_respoutrp; /* register for RESOUTP */
/*
* Instrumentation
*/
u_int64_t isp_intcnt; /* total int count */
u_int64_t isp_intbogus; /* spurious int count */
/*
* Volatile state
*/
volatile u_int32_t
isp_mboxbsy : 8, /* mailbox command active */
: 1,
isp_state : 3,
isp_sendmarker : 2, /* send a marker entry */
isp_update : 2, /* update parameters */
isp_nactive : 16; /* how many commands active */
volatile u_int16_t isp_reqodx; /* index of last ISP pickup */
volatile u_int16_t isp_reqidx; /* index of next request */
volatile u_int16_t isp_residx; /* index of next result */
volatile u_int16_t isp_lasthdls; /* last handle seed */
volatile u_int16_t isp_mboxtmp[MAX_MAILBOX];
volatile u_int16_t isp_lastmbxcmd; /* last mbox command sent */
/*
* Active commands are stored here, indexed by handle functions.
*/
XS_T **isp_xflist;
/*
* request/result queue pointers and dma handles for them.
*/
caddr_t isp_rquest;
caddr_t isp_result;
ISP_DMA_ADDR_T isp_rquest_dma;
ISP_DMA_ADDR_T isp_result_dma;
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} ispsoftc_t;
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#define SDPARAM(isp) ((sdparam *) (isp)->isp_param)
#define FCPARAM(isp) ((fcparam *) (isp)->isp_param)
/*
* ISP Driver Run States
*/
#define ISP_NILSTATE 0
#define ISP_RESETSTATE 1
#define ISP_INITSTATE 2
#define ISP_RUNSTATE 3
/*
* ISP Configuration Options
*/
#define ISP_CFG_NORELOAD 0x80 /* don't download f/w */
#define ISP_CFG_NONVRAM 0x40 /* ignore NVRAM */
#define ISP_CFG_FULL_DUPLEX 0x01 /* Full Duplex (Fibre Channel only) */
#define ISP_CFG_OWNWWN 0x02 /* override NVRAM wwn */
#define ISP_CFG_PORT_PREF 0x0C /* Mask for Port Prefs (2200 only) */
#define ISP_CFG_LPORT 0x00 /* prefer {N/F}L-Port connection */
#define ISP_CFG_NPORT 0x04 /* prefer {N/F}-Port connection */
#define ISP_CFG_NPORT_ONLY 0x08 /* insist on {N/F}-Port connection */
#define ISP_CFG_LPORT_ONLY 0x0C /* insist on {N/F}L-Port connection */
/*
* Prior to calling isp_reset for the first time, the outer layer
* should set isp_role to one of NONE, INITIATOR, TARGET, BOTH.
*
* If you set ISP_ROLE_NONE, the cards will be reset, new firmware loaded,
* NVRAM read, and defaults set, but any further initialization (e.g.
* INITIALIZE CONTROL BLOCK commands for 2X00 cards) won't be done.
*
* If INITIATOR MODE isn't set, attempts to run commands will be stopped
* at isp_start and completed with the moral equivalent of SELECTION TIMEOUT.
*
* If TARGET MODE is set, it doesn't mean that the rest of target mode support
* needs to be enabled, or will even work. What happens with the 2X00 cards
* here is that if you have enabled it with TARGET MODE as part of the ICB
* options, but you haven't given the f/w any ram resources for ATIOs or
* Immediate Notifies, the f/w just handles what it can and you never see
* anything. Basically, it sends a single byte of data (the first byte,
* which you can set as part of the INITIALIZE CONTROL BLOCK command) for
* INQUIRY, and sends back QUEUE FULL status for any other command.
*
*/
#define ISP_ROLE_NONE 0x0
#define ISP_ROLE_INITIATOR 0x1
#define ISP_ROLE_TARGET 0x2
#define ISP_ROLE_BOTH (ISP_ROLE_TARGET|ISP_ROLE_INITIATOR)
#define ISP_ROLE_EITHER ISP_ROLE_BOTH
#ifndef ISP_DEFAULT_ROLES
#define ISP_DEFAULT_ROLES ISP_ROLE_INITIATOR
#endif
/*
* Firmware related defines
*/
#define ISP_CODE_ORG 0x1000 /* default f/w code start */
#define ISP_CODE_ORG_2300 0x0800 /* ..except for 2300s */
#define ISP_FW_REV(maj, min, mic) ((maj << 24) | (min << 16) | mic)
#define ISP_FW_MAJOR(code) ((code >> 24) & 0xff)
#define ISP_FW_MINOR(code) ((code >> 16) & 0xff)
#define ISP_FW_MICRO(code) ((code >> 8) & 0xff)
#define ISP_FW_REVX(xp) ((xp[0]<<24) | (xp[1] << 16) | xp[2])
#define ISP_FW_MAJORX(xp) (xp[0])
#define ISP_FW_MINORX(xp) (xp[1])
#define ISP_FW_MICROX(xp) (xp[2])
/*
* Bus (implementation) types
*/
#define ISP_BT_PCI 0 /* PCI Implementations */
#define ISP_BT_SBUS 1 /* SBus Implementations */
/*
* Chip Types
*/
#define ISP_HA_SCSI 0xf
#define ISP_HA_SCSI_UNKNOWN 0x1
#define ISP_HA_SCSI_1020 0x2
#define ISP_HA_SCSI_1020A 0x3
#define ISP_HA_SCSI_1040 0x4
#define ISP_HA_SCSI_1040A 0x5
#define ISP_HA_SCSI_1040B 0x6
#define ISP_HA_SCSI_1040C 0x7
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#define ISP_HA_SCSI_1240 0x8
#define ISP_HA_SCSI_1080 0x9
#define ISP_HA_SCSI_1280 0xa
#define ISP_HA_SCSI_12160 0xb
#define ISP_HA_FC 0xf0
#define ISP_HA_FC_2100 0x10
#define ISP_HA_FC_2200 0x20
Spring MegaChange #1. ---- Make a device for each ISP- really usable only with devfs and add an ioctl entry point (this can be used to (re)set debug levels, reset the HBA, rescan the fabric, issue lips, etc). ---- Add in a kernel thread for Fibre Channel cards. The purpose of this thread is to be woken up to clean up after Fibre Channel events block things. Basically, any FC event that casts doubt on the location or identify of FC devices blocks the queues. When, and if, we get the PORT DATABASE CHANGED or NAME SERVER DATABASE CHANGED async event, we activate the kthread which will then, in full thread context, re-evaluate the local loop and/or the fabric. When it's satisfied that things are stable, it can then release the blocked queues and let commands flow again. The prior mechanism was a lazy evaluation. That is, the next command to come down the pipe after change events would pay the full price for re-evaluation. And if this was done off of a softcall, it really could hang up the system. These changes brings the FreeBSD port more in line with the Solaris, Linux and NetBSD ports. It also, more importantly, gets us being more proactive about topology changes which could then be reflected upwards to CAM so that the periph driver can be informed sooner rather than later when things arrive or depart. --- Add in the (correct) usage of locking macros- we now have lock transition macros which allow us to transition from holding the CAM lock (Giant) and grabbing the softc lock and vice versa. Switch over to having this HBA do real locking. Some folks claim this won't be a win. They're right. But you have to start somewhere, and this will begin to teach us how to DTRT for HBAs, etc. -- Start putting in prototype 2300 support. Add back in LIP and Loop Reset as async events that each platform will handle. Add in another int_bogus instrumentation point. Do some more substantial target mode cleanups. MFC after: 8 weeks
2001-05-28 21:20:43 +00:00
#define ISP_HA_FC_2300 0x30
#define IS_SCSI(isp) (isp->isp_type & ISP_HA_SCSI)
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#define IS_1240(isp) (isp->isp_type == ISP_HA_SCSI_1240)
#define IS_1080(isp) (isp->isp_type == ISP_HA_SCSI_1080)
1999-12-16 05:42:02 +00:00
#define IS_1280(isp) (isp->isp_type == ISP_HA_SCSI_1280)
#define IS_12160(isp) (isp->isp_type == ISP_HA_SCSI_12160)
#define IS_12X0(isp) (IS_1240(isp) || IS_1280(isp))
#define IS_DUALBUS(isp) (IS_12X0(isp) || IS_12160(isp))
#define IS_ULTRA2(isp) (IS_1080(isp) || IS_1280(isp) || IS_12160(isp))
#define IS_ULTRA3(isp) (IS_12160(isp))
Spring MegaChange #1. ---- Make a device for each ISP- really usable only with devfs and add an ioctl entry point (this can be used to (re)set debug levels, reset the HBA, rescan the fabric, issue lips, etc). ---- Add in a kernel thread for Fibre Channel cards. The purpose of this thread is to be woken up to clean up after Fibre Channel events block things. Basically, any FC event that casts doubt on the location or identify of FC devices blocks the queues. When, and if, we get the PORT DATABASE CHANGED or NAME SERVER DATABASE CHANGED async event, we activate the kthread which will then, in full thread context, re-evaluate the local loop and/or the fabric. When it's satisfied that things are stable, it can then release the blocked queues and let commands flow again. The prior mechanism was a lazy evaluation. That is, the next command to come down the pipe after change events would pay the full price for re-evaluation. And if this was done off of a softcall, it really could hang up the system. These changes brings the FreeBSD port more in line with the Solaris, Linux and NetBSD ports. It also, more importantly, gets us being more proactive about topology changes which could then be reflected upwards to CAM so that the periph driver can be informed sooner rather than later when things arrive or depart. --- Add in the (correct) usage of locking macros- we now have lock transition macros which allow us to transition from holding the CAM lock (Giant) and grabbing the softc lock and vice versa. Switch over to having this HBA do real locking. Some folks claim this won't be a win. They're right. But you have to start somewhere, and this will begin to teach us how to DTRT for HBAs, etc. -- Start putting in prototype 2300 support. Add back in LIP and Loop Reset as async events that each platform will handle. Add in another int_bogus instrumentation point. Do some more substantial target mode cleanups. MFC after: 8 weeks
2001-05-28 21:20:43 +00:00
#define IS_FC(isp) ((isp)->isp_type & ISP_HA_FC)
#define IS_2100(isp) ((isp)->isp_type == ISP_HA_FC_2100)
#define IS_2200(isp) ((isp)->isp_type == ISP_HA_FC_2200)
#define IS_2300(isp) ((isp)->isp_type >= ISP_HA_FC_2300)
/*
* DMA cookie macros
*/
#define DMA_WD3(x) 0
#define DMA_WD2(x) 0
#define DMA_WD1(x) (((x) >> 16) & 0xffff)
#define DMA_WD0(x) (((x) & 0xffff))
/*
* Core System Function Prototypes
*/
/*
* Reset Hardware. Totally. Assumes that you'll follow this with
* a call to isp_init.
*/
void isp_reset(struct ispsoftc *);
/*
* Initialize Hardware to known state
*/
void isp_init(struct ispsoftc *);
/*
* Reset the ISP and call completion for any orphaned commands.
*/
void isp_reinit(struct ispsoftc *);
/*
* Internal Interrupt Service Routine
*
* The outer layers do the spade work to get the appropriate status register,
* semaphore register and first mailbox register (if appropriate). This also
* means that most spurious/bogus interrupts not for us can be filtered first.
*/
void isp_intr(struct ispsoftc *, u_int16_t, u_int16_t, u_int16_t);
/*
* Command Entry Point- Platform Dependent layers call into this
*/
int isp_start(XS_T *);
/* these values are what isp_start returns */
#define CMD_COMPLETE 101 /* command completed */
#define CMD_EAGAIN 102 /* busy- maybe retry later */
#define CMD_QUEUED 103 /* command has been queued for execution */
#define CMD_RQLATER 104 /* requeue this command later */
/*
* Command Completion Point- Core layers call out from this with completed cmds
*/
void isp_done(XS_T *);
/*
* Platform Dependent to External to Internal Control Function
*
* Assumes locks are held on entry. You should note that with many of
* these commands and locks may be released while this is occurring.
*
* A few notes about some of these functions:
*
* ISPCTL_FCLINK_TEST tests to make sure we have good fibre channel link.
* The argument is a pointer to an integer which is the time, in microseconds,
* we should wait to see whether we have good link. This test, if successful,
* lets us know our connection topology and our Loop ID/AL_PA and so on.
* You can't get anywhere without this.
*
* ISPCTL_SCAN_FABRIC queries the name server (if we're on a fabric) for
* all entities using the FC Generic Services subcommand GET ALL NEXT.
* For each found entity, an ISPASYNC_FABRICDEV event is generated (see
* below).
*
* ISPCTL_SCAN_LOOP does a local loop scan. This is only done if the connection
* topology is NL or FL port (private or public loop). Since the Qlogic f/w
* 'automatically' manages local loop connections, this function essentially
* notes the arrival, departure, and possible shuffling around of local loop
* entities. Thus for each arrival and departure this generates an isp_async
* event of ISPASYNC_PROMENADE (see below).
*
* ISPCTL_PDB_SYNC is somewhat misnamed. It actually is the final step, in
* order, of ISPCTL_FCLINK_TEST, ISPCTL_SCAN_FABRIC, and ISPCTL_SCAN_LOOP.
* The main purpose of ISPCTL_PDB_SYNC is to complete management of logging
* and logging out of fabric devices (if one is on a fabric) and then marking
* the 'loop state' as being ready to now be used for sending commands to
* devices. Originally fabric name server and local loop scanning were
2001-08-16 17:31:27 +00:00
* part of this function. It's now been separated to allow for finer control.
*/
typedef enum {
ISPCTL_RESET_BUS, /* Reset Bus */
ISPCTL_RESET_DEV, /* Reset Device */
ISPCTL_ABORT_CMD, /* Abort Command */
ISPCTL_UPDATE_PARAMS, /* Update Operating Parameters (SCSI) */
ISPCTL_FCLINK_TEST, /* Test FC Link Status */
ISPCTL_SCAN_FABRIC, /* (Re)scan Fabric Name Server */
ISPCTL_SCAN_LOOP, /* (Re)scan Local Loop */
ISPCTL_PDB_SYNC, /* Synchronize Port Database */
ISPCTL_SEND_LIP, /* Send a LIP */
ISPCTL_GET_POSMAP, /* Get FC-AL position map */
ISPCTL_RUN_MBOXCMD, /* run a mailbox command */
ISPCTL_TOGGLE_TMODE /* toggle target mode */
} ispctl_t;
int isp_control(struct ispsoftc *, ispctl_t, void *);
/*
* Platform Dependent to Internal to External Control Function
* (each platform must provide such a function)
*
* Assumes locks are held.
*
* A few notes about some of these functions:
*
* ISPASYNC_CHANGE_NOTIFY notifies the outer layer that a change has
* occurred that invalidates the list of fabric devices known and/or
* the list of known loop devices. The argument passed is a pointer
* whose values are defined below (local loop change, name server
* change, other). 'Other' may simply be a LIP, or a change in
* connection topology.
*
* ISPASYNC_FABRIC_DEV announces the next element in a list of
* fabric device names we're getting out of the name server. The
* argument points to a GET ALL NEXT response structure. The list
* is known to terminate with an entry that refers to ourselves.
* One of the main purposes of this function is to allow outer
* layers, which are OS dependent, to set policy as to which fabric
* devices might actually be logged into (and made visible) later
* at ISPCTL_PDB_SYNC time. Since there's a finite number of fabric
* devices that we can log into (256 less 3 'reserved' for F-port
* topologies), and fabrics can grow up to 8 million or so entries
* (24 bits of Port Address, less a wad of reserved spaces), clearly
* we had better let the OS determine login policy.
*
* ISPASYNC_PROMENADE has an argument that is a pointer to an integer which
* is an index into the portdb in the softc ('target'). Whether that entrie's
* valid tag is set or not says whether something has arrived or departed.
* The name refers to a favorite pastime of many city dwellers- watching
* people come and go, talking of Michaelangelo, and so on..
*
* ISPASYNC_UNHANDLED_RESPONSE gives outer layers a chance to parse a
* response queue entry not otherwise handled. The outer layer should
* return non-zero if it handled it. The 'arg' points to a (possibly only
* partially) massaged response queue entry (see the platform's
* ISP_UNSWIZZLE_RESPONSE macro).
*/
typedef enum {
ISPASYNC_NEW_TGT_PARAMS, /* New Target Parameters Negotiated */
ISPASYNC_BUS_RESET, /* Bus Was Reset */
ISPASYNC_LOOP_DOWN, /* FC Loop Down */
ISPASYNC_LOOP_UP, /* FC Loop Up */
Spring MegaChange #1. ---- Make a device for each ISP- really usable only with devfs and add an ioctl entry point (this can be used to (re)set debug levels, reset the HBA, rescan the fabric, issue lips, etc). ---- Add in a kernel thread for Fibre Channel cards. The purpose of this thread is to be woken up to clean up after Fibre Channel events block things. Basically, any FC event that casts doubt on the location or identify of FC devices blocks the queues. When, and if, we get the PORT DATABASE CHANGED or NAME SERVER DATABASE CHANGED async event, we activate the kthread which will then, in full thread context, re-evaluate the local loop and/or the fabric. When it's satisfied that things are stable, it can then release the blocked queues and let commands flow again. The prior mechanism was a lazy evaluation. That is, the next command to come down the pipe after change events would pay the full price for re-evaluation. And if this was done off of a softcall, it really could hang up the system. These changes brings the FreeBSD port more in line with the Solaris, Linux and NetBSD ports. It also, more importantly, gets us being more proactive about topology changes which could then be reflected upwards to CAM so that the periph driver can be informed sooner rather than later when things arrive or depart. --- Add in the (correct) usage of locking macros- we now have lock transition macros which allow us to transition from holding the CAM lock (Giant) and grabbing the softc lock and vice versa. Switch over to having this HBA do real locking. Some folks claim this won't be a win. They're right. But you have to start somewhere, and this will begin to teach us how to DTRT for HBAs, etc. -- Start putting in prototype 2300 support. Add back in LIP and Loop Reset as async events that each platform will handle. Add in another int_bogus instrumentation point. Do some more substantial target mode cleanups. MFC after: 8 weeks
2001-05-28 21:20:43 +00:00
ISPASYNC_LIP, /* LIP Received */
ISPASYNC_LOOP_RESET, /* Loop Reset Received */
ISPASYNC_CHANGE_NOTIFY, /* FC Change Notification */
ISPASYNC_FABRIC_DEV, /* FC Fabric Device Arrival */
ISPASYNC_PROMENADE, /* FC Objects coming && going */
ISPASYNC_TARGET_MESSAGE, /* target message */
ISPASYNC_TARGET_EVENT, /* target asynchronous event */
ISPASYNC_TARGET_ACTION, /* other target command action */
ISPASYNC_CONF_CHANGE, /* Platform Configuration Change */
ISPASYNC_UNHANDLED_RESPONSE, /* Unhandled Response Entry */
ISPASYNC_FW_CRASH /* Firmware has crashed */
} ispasync_t;
int isp_async(struct ispsoftc *, ispasync_t, void *);
#define ISPASYNC_CHANGE_PDB ((void *) 0)
#define ISPASYNC_CHANGE_SNS ((void *) 1)
#define ISPASYNC_CHANGE_OTHER ((void *) 2)
/*
* Platform Dependent Error and Debug Printout
*/
#ifdef __GNUC__
void isp_prt(struct ispsoftc *, int level, const char *, ...)
__attribute__((__format__(__printf__,3,4)));
#else
void isp_prt(struct ispsoftc *, int level, const char *, ...);
#endif
#define ISP_LOGALL 0x0 /* log always */
#define ISP_LOGCONFIG 0x1 /* log configuration messages */
#define ISP_LOGINFO 0x2 /* log informational messages */
#define ISP_LOGWARN 0x4 /* log warning messages */
#define ISP_LOGERR 0x8 /* log error messages */
#define ISP_LOGDEBUG0 0x10 /* log simple debug messages */
#define ISP_LOGDEBUG1 0x20 /* log intermediate debug messages */
#define ISP_LOGDEBUG2 0x40 /* log most debug messages */
#define ISP_LOGDEBUG3 0x80 /* log high frequency debug messages */
#define ISP_LOGDEBUG4 0x100 /* log high frequency debug messages */
#define ISP_LOGTDEBUG0 0x200 /* log simple debug messages (target mode) */
#define ISP_LOGTDEBUG1 0x400 /* log intermediate debug messages (target) */
#define ISP_LOGTDEBUG2 0x800 /* log all debug messages (target) */
/*
* Each Platform provides it's own isposinfo substructure of the ispsoftc
* defined above.
*
* Each platform must also provide the following macros/defines:
*
*
* INLINE - platform specific define for 'inline' functions
*
* ISP_DMA_ADDR_T - platform specific dma address coookie- basically
* the largest integer that can hold the 32 or
* 64 bit value appropriate for the QLogic's DMA
* addressing. Defaults to u_int32_t.
*
* ISP2100_SCRLEN - length for the Fibre Channel scratch DMA area
*
* MEMZERO(dst, src) platform zeroing function
* MEMCPY(dst, src, count) platform copying function
* SNPRINTF(buf, bufsize, fmt, ...) snprintf
* STRNCAT(dstbuf, size, srcbuf) strncat
* USEC_DELAY(usecs) microsecond spindelay function
* USEC_SLEEP(isp, usecs) microsecond sleep function
*
* NANOTIME_T nanosecond time type
*
* GET_NANOTIME(NANOTIME_T *) get current nanotime.
*
* GET_NANOSEC(NANOTIME_T *) get u_int64_t from NANOTIME_T
*
* NANOTIME_SUB(NANOTIME_T *, NANOTIME_T *)
* subtract two NANOTIME_T values
*
*
* MAXISPREQUEST(struct ispsoftc *) maximum request queue size
* for this particular board type
*
* MEMORYBARRIER(struct ispsoftc *, barrier_type, offset, size)
*
* Function/Macro the provides memory synchronization on
* various objects so that the ISP's and the system's view
* of the same object is consistent.
*
* MBOX_ACQUIRE(struct ispsoftc *) acquire lock on mailbox regs
* MBOX_WAIT_COMPLETE(struct ispsoftc *) wait for mailbox cmd to be done
* MBOX_NOTIFY_COMPLETE(struct ispsoftc *) notification of mbox cmd donee
* MBOX_RELEASE(struct ispsoftc *) release lock on mailbox regs
*
*
* SCSI_GOOD SCSI 'Good' Status
* SCSI_CHECK SCSI 'Check Condition' Status
* SCSI_BUSY SCSI 'Busy' Status
* SCSI_QFULL SCSI 'Queue Full' Status
*
* XS_T Platform SCSI transaction type (i.e., command for HBA)
* XS_ISP(xs) gets an instance out of an XS_T
* XS_CHANNEL(xs) gets the channel (bus # for DUALBUS cards) ""
* XS_TGT(xs) gets the target ""
* XS_LUN(xs) gets the lun ""
* XS_CDBP(xs) gets a pointer to the scsi CDB ""
* XS_CDBLEN(xs) gets the CDB's length ""
* XS_XFRLEN(xs) gets the associated data transfer length ""
* XS_TIME(xs) gets the time (in milliseconds) for this command
* XS_RESID(xs) gets the current residual count
* XS_STSP(xs) gets a pointer to the SCSI status byte ""
* XS_SNSP(xs) gets a pointer to the associate sense data
* XS_SNSLEN(xs) gets the length of sense data storage
* XS_SNSKEY(xs) dereferences XS_SNSP to get the current stored Sense Key
* XS_TAG_P(xs) predicate of whether this command should be tagged
* XS_TAG_TYPE(xs) which type of tag to use
* XS_SETERR(xs) set error state
*
* HBA_NOERROR command has no erros
* HBA_BOTCH hba botched something
* HBA_CMDTIMEOUT command timed out
* HBA_SELTIMEOUT selection timed out (also port logouts for FC)
* HBA_TGTBSY target returned a BUSY status
* HBA_BUSRESET bus reset destroyed command
* HBA_ABORTED command was aborted (by request)
* HBA_DATAOVR a data overrun was detected
* HBA_ARQFAIL Automatic Request Sense failed
*
* XS_ERR(xs) return current error state
* XS_NOERR(xs) there is no error currently set
* XS_INITERR(xs) initialize error state
*
* XS_SAVE_SENSE(xs, sp) save sense data
*
* XS_SET_STATE_STAT(isp, sp, xs) platform dependent interpreter of
* response queue entry status bits
*
*
* DEFAULT_IID(struct ispsoftc *) Default SCSI initiator ID
* DEFAULT_LOOPID(struct ispsoftc *) Default FC Loop ID
* DEFAULT_NODEWWN(struct ispsoftc *) Default Node WWN
* DEFAULT_PORTWWN(struct ispsoftc *) Default Port WWN
* These establish reasonable defaults for each platform.
* These must be available independent of card NVRAM and are
* to be used should NVRAM not be readable.
*
* ISP_NODEWWN(struct ispsoftc *) FC Node WWN to use
* ISP_PORTWWN(struct ispsoftc *) FC Port WWN to use
*
* These are to be used after NVRAM is read. The tags
* in fcparam.isp_{node,port}wwn reflect the values
* read from NVRAM (possibly corrected for card botches).
* Each platform can take that information and override
* it or ignore and return the Node and Port WWNs to be
* used when sending the Qlogic f/w the Initialization Control
* Block.
*
* (XXX these do endian specific transformations- in transition XXX)
* ISP_SWIZZLE_ICB
* ISP_UNSWIZZLE_AND_COPY_PDBP
* ISP_SWIZZLE_CONTINUATION
* ISP_SWIZZLE_REQUEST
* ISP_UNSWIZZLE_RESPONSE
* ISP_SWIZZLE_SNS_REQ
* ISP_UNSWIZZLE_SNS_RSP
* ISP_SWIZZLE_NVRAM_WORD
*/
Spring MegaChange #1. ---- Make a device for each ISP- really usable only with devfs and add an ioctl entry point (this can be used to (re)set debug levels, reset the HBA, rescan the fabric, issue lips, etc). ---- Add in a kernel thread for Fibre Channel cards. The purpose of this thread is to be woken up to clean up after Fibre Channel events block things. Basically, any FC event that casts doubt on the location or identify of FC devices blocks the queues. When, and if, we get the PORT DATABASE CHANGED or NAME SERVER DATABASE CHANGED async event, we activate the kthread which will then, in full thread context, re-evaluate the local loop and/or the fabric. When it's satisfied that things are stable, it can then release the blocked queues and let commands flow again. The prior mechanism was a lazy evaluation. That is, the next command to come down the pipe after change events would pay the full price for re-evaluation. And if this was done off of a softcall, it really could hang up the system. These changes brings the FreeBSD port more in line with the Solaris, Linux and NetBSD ports. It also, more importantly, gets us being more proactive about topology changes which could then be reflected upwards to CAM so that the periph driver can be informed sooner rather than later when things arrive or depart. --- Add in the (correct) usage of locking macros- we now have lock transition macros which allow us to transition from holding the CAM lock (Giant) and grabbing the softc lock and vice versa. Switch over to having this HBA do real locking. Some folks claim this won't be a win. They're right. But you have to start somewhere, and this will begin to teach us how to DTRT for HBAs, etc. -- Start putting in prototype 2300 support. Add back in LIP and Loop Reset as async events that each platform will handle. Add in another int_bogus instrumentation point. Do some more substantial target mode cleanups. MFC after: 8 weeks
2001-05-28 21:20:43 +00:00
#endif /* _ISPVAR_H */