/* $OpenBSD: ispvar.h,v 1.26 2008/11/02 03:17:22 krw Exp $ */ /* $FreeBSD: src/sys/dev/isp/ispvar.h,v 1.85 2007/07/02 20:08:20 mjacob Exp $ */ /*- * Copyright (c) 1997-2007 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, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY 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 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. */ /* * Soft Definitions for for Qlogic ISP SCSI adapters. */ #ifndef _ISPVAR_H #define _ISPVAR_H #if defined(__NetBSD__) || defined(__OpenBSD__) #include #include #ifdef ISP_TARGET_MODE #include #include #endif #endif #ifdef __FreeBSD__ #include #include #ifdef ISP_TARGET_MODE #include #include #endif #endif #ifdef __linux__ #include "isp_stds.h" #include "ispmbox.h" #ifdef ISP_TARGET_MODE #include "isp_target.h" #include "isp_tpublic.h" #endif #endif #define ISP_CORE_VERSION_MAJOR 2 #define ISP_CORE_VERSION_MINOR 7 /* * 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 *); 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 #define ISP_MAX_TARGETS(isp) (IS_FC(isp)? MAX_FC_TARG : MAX_TARGETS) #define ISP_MAX_LUNS(isp) (isp)->isp_maxluns /* * 'Types' */ #ifdef ISP_DAC_SUPPORTED typedef u_int64_t isp_dma_addr_t; #else typedef u_int32_t isp_dma_addr_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 */ #define SYNC_ATIOQ 5 /* atio result queue (24xx) */ /* * 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) #ifdef ISP_TARGET_MODE #define RESULT_QUEUE_LEN(x) MAXISPREQUEST(x) #else #define RESULT_QUEUE_LEN(x) \ (((MAXISPREQUEST(x) >> 2) < 64)? 64 : MAXISPREQUEST(x) >> 2) #endif #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)) #define ISP_QFREE(in, out, qlen) \ ((in == out)? (qlen - 1) : ((in > out)? \ ((qlen - 1) - (in - out)) : (out - in - 1))) #define ISP_QAVAIL(isp) \ ISP_QFREE(isp->isp_reqidx, isp->isp_reqodx, RQUEST_QUEUE_LEN(isp)) #define ISP_ADD_REQUEST(isp, nxti) \ MEMORYBARRIER(isp, SYNC_REQUEST, isp->isp_reqidx, QENTRY_LEN); \ WRITE_REQUEST_QUEUE_IN_POINTER(isp, nxti); \ isp->isp_reqidx = nxti /* * 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, 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 #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 */ #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 */ /* #define ISP_USE_GA_NXT 1 */ /* Use GA_NXT with switches */ #ifndef GA_NXT_MAX #define GA_NXT_MAX 256 #endif /* These are for 2K Login Firmware cards */ #define NPH_RESERVED 0x7F0 /* begin of reserved N-port handles */ #define NPH_MGT_ID 0x7FA /* Management Server Special ID */ #define NPH_SNS_ID 0x7FC /* SNS Server Special ID */ #define NPH_FL_ID 0x7FE /* FL Port Special ID */ #define NPH_MAX_2K 0x800 /* * "Unassigned" handle to be used internally */ #define NIL_HANDLE 0xffff /* * Limit for devices on an arbitrated loop. */ #define LOCAL_LOOP_LIM 126 /* * Special Port IDs */ #define MANAGEMENT_PORT_ID 0xFFFFFA #define SNS_PORT_ID 0xFFFFFC #define FABRIC_PORT_ID 0xFFFFFE /* * FC Port Database entry. * * It has a handle that the f/w uses to address commands to a device. * This handle's value may be assigned by the firmware (e.g., for local loop * devices) or by the driver (e.g., for fabric devices). * * It has a state. If the state if VALID, that means that we've logged into * the device. We also *may* have a initiator map index entry. This is a value * from 0..MAX_FC_TARG that is used to index into the isp_ini_map array. If * the value therein is non-zero, then that value minus one is used to index * into the Port Database to find the handle for forming commands. There is * back-index minus one value within to Port Database entry that tells us * which entry in isp_ini_map points to us (to avoid searching). * * Local loop devices the firmware automatically performs PLOGI on for us * (which is why that handle is imposed upon us). Fabric devices we assign * a handle to and perform the PLOGI on. * * When a PORT DATABASE CHANGED asynchronous event occurs, we mark all VALID * entries as PROBATIONAL. This allows us, if policy says to, just keep track * of devices whose handles change but are otherwise the same device (and * thus keep 'target' constant). * * In any case, we search all possible local loop handles. For each one that * has a port database entity returned, we search for any PROBATIONAL entry * that matches it and update as appropriate. Otherwise, as a new entry, we * find room for it in the Port Database. We *try* and use the handle as the * index to put it into the Database, but that's just an optimization. We mark * the entry VALID and make sure that the target index is updated and correct. * * When we get done searching the local loop, we then search similarily for * a list of devices we've gotten from the fabric name controller (if we're * on a fabric). VALID marking is also done similarily. * * When all of this is done, we can march through the database and clean up * any entry that is still PROBATIONAL (these represent devices which have * departed). Then we're done and can resume normal operations. * * Negative invariants that we try and test for are: * * + There can never be two non-NIL entries with the same { Port, Node } WWN * duples. * * + There can never be two non-NIL entries with the same handle. * * + There can never be two non-NIL entries which have the same ini_map_idx * value. */ typedef struct { u_int32_t isp_fwoptions : 16, isp_gbspeed : 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_int32_t port_type : 8, loopid : 8, fc4_type : 4, last_fabric_dev : 1, : 2, relogin : 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; #ifdef ISP_FW_CRASH_DUMP u_int16_t *isp_dump_data; #endif } 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 */ 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 */ : 4, isp_port : 1, /* 23XX/24XX only */ isp_failed : 1, /* board failed */ isp_open : 1, /* opened (ioctl) */ isp_touched : 1, /* board ever seen? */ isp_bustype : 1, /* SBus or PCI */ isp_loaded_fw : 1, /* loaded firmware */ isp_role : 2, /* roles supported */ 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 */ u_int64_t isp_intmboxc; /* mbox completions */ u_int64_t isp_intoasync; /* other async */ u_int64_t isp_rsltccmplt; /* CMDs on result q */ u_int64_t isp_fphccmplt; /* CMDs via fastpost */ u_int16_t isp_rscchiwater; u_int16_t isp_fpcchiwater; /* * Volatile state */ volatile u_int32_t isp_obits : 8, /* mailbox command output */ isp_mboxbsy : 1, /* mailbox command active */ 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_resodx; /* index of next result */ volatile u_int16_t isp_rspbsy; 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 */ volatile u_int16_t isp_mbxwrk0; volatile u_int16_t isp_mbxwrk1; volatile u_int16_t isp_mbxwrk2; void * isp_mbxworkp; /* * 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; } ispsoftc_t; #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_TWOGB 0x20 /* force 2GB connection (23XX only) */ #define ISP_CFG_ONEGB 0x10 /* force 1GB connection (23XX only) */ #define ISP_CFG_FULL_DUPLEX 0x01 /* Full Duplex (Fibre Channel only) */ #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 */ #define ISP_CFG_OWNWWPN 0x100 /* override NVRAM wwpn */ #define ISP_CFG_OWNWWNN 0x200 /* override NVRAM wwnn */ #define ISP_CFG_OWNFSZ 0x400 /* override NVRAM frame size */ #define ISP_CFG_OWNLOOPID 0x800 /* override NVRAM loopid */ #define ISP_CFG_OWNEXCTHROTTLE 0x1000 /* override NVRAM execution throttle */ #define ISP_CFG_FOURGB 0x2000 /* force 4GB connection (24XX only) */ /* * 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_CODE_ORG_2400 0x100000 /* ..and 2400s */ #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]) #define ISP_FW_NEWER_THAN(i, major, minor, micro) \ (ISP_FW_REVX((i)->isp_fwrev) > ISP_FW_REV(major, minor, micro)) #define ISP_FW_OLDER_THAN(i, major, minor, micro) \ (ISP_FW_REVX((i)->isp_fwrev) < ISP_FW_REV(major, minor, micro)) /* * Bus (implementation) types */ #define ISP_BT_PCI 0 /* PCI Implementations */ #define ISP_BT_SBUS 1 /* SBus Implementations */ /* * If we have not otherwise defined SBus support away make sure * it is defined here such that the code is included as default */ #ifndef ISP_SBUS_SUPPORTED #define ISP_SBUS_SUPPORTED 1 #endif /* * 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 #define ISP_HA_SCSI_1240 0x8 #define ISP_HA_SCSI_1080 0x9 #define ISP_HA_SCSI_1280 0xa #define ISP_HA_SCSI_10160 0xb #define ISP_HA_SCSI_12160 0xc #define ISP_HA_FC 0xf0 #define ISP_HA_FC_2100 0x10 #define ISP_HA_FC_2200 0x20 #define ISP_HA_FC_2300 0x30 #define ISP_HA_FC_2312 0x40 #define ISP_HA_FC_2322 0x50 #define ISP_HA_FC_2400 0x60 #define IS_SCSI(isp) (isp->isp_type & ISP_HA_SCSI) #define IS_1240(isp) (isp->isp_type == ISP_HA_SCSI_1240) #define IS_1080(isp) (isp->isp_type == ISP_HA_SCSI_1080) #define IS_1280(isp) (isp->isp_type == ISP_HA_SCSI_1280) #define IS_10160(isp) (isp->isp_type == ISP_HA_SCSI_10160) #define IS_12160(isp) (isp->isp_type == ISP_HA_SCSI_12160) #define IS_12X0(isp) (IS_1240(isp) || IS_1280(isp)) #define IS_1X160(isp) (IS_10160(isp) || IS_12160(isp)) #define IS_DUALBUS(isp) (IS_12X0(isp) || IS_12160(isp)) #define IS_ULTRA2(isp) (IS_1080(isp) || IS_1280(isp) || IS_1X160(isp)) #define IS_ULTRA3(isp) (IS_1X160(isp)) #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_23XX(isp) ((isp)->isp_type >= ISP_HA_FC_2300) #define IS_2300(isp) ((isp)->isp_type == ISP_HA_FC_2300) #define IS_2312(isp) ((isp)->isp_type == ISP_HA_FC_2312) #define IS_2322(isp) ((isp)->isp_type == ISP_HA_FC_2322) #define IS_24XX(isp) ((isp)->isp_type >= ISP_HA_FC_2400) /* * DMA related macros */ #ifdef ISP_DAC_SUPPORTRED #define DMA_WD3(x) (((x) >> 48) & 0xffff) #define DMA_WD2(x) (((x) >> 32) & 0xffff) #else #define DMA_WD3(x) 0 #define DMA_WD2(x) 0 #endif #define DMA_WD1(x) (((x) >> 16) & 0xffff) #define DMA_WD0(x) (((x) & 0xffff)) #define DMA_LO32(x) ((u_int32_t) (x)) #define DMA_HI32(x) ((u_int32_t)(((u_int64_t)x) >> 32)) /* * 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 *); #ifdef ISP_FW_CRASH_DUMP /* * Dump firmware entry point. */ void isp_fw_dump(struct ispsoftc *isp); #endif /* * 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 * 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 entry'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 an unmassaged * response queue entry. */ 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 */ 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_FW_DUMPED, /* Firmware crashdump taken */ ISPASYNC_FW_RESTARTED /* Firmware has been restarted */ } 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 * * Generally this is: * * void isp_prt(struct ispsoftc *, int level, const char *, ...) * * but due to compiler differences on different platforms this won't be * formally done here. Instead, it goes in each platform definition file. */ #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: * * * 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 * 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 * * FC_SCRATCH_ACQUIRE(struct ispsoftc *) acquire lock on FC scratch area * FC_SCRATCH_RELEASE(struct ispsoftc *) acquire lock on FC scratch area * * 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 * DEFAULT_FRAMESIZE(struct ispsoftc *) Default Frame Size * DEFAULT_EXEC_THROTTLE(struct ispsoftc *) Default Execution Throttle * 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_IOXPUT_8(struct ispsoftc *, u_int8_t srcval, u_int8_t *dstptr) * ISP_IOXPUT_16(struct ispsoftc *, u_int16_t srcval, u_int16_t *dstptr) * ISP_IOXPUT_32(struct ispsoftc *, u_int32_t srcval, u_int32_t *dstptr) * * ISP_IOXGET_8(struct ispsoftc *, u_int8_t *srcptr, u_int8_t dstrval) * ISP_IOXGET_16(struct ispsoftc *, u_int16_t *srcptr, u_int16_t dstrval) * ISP_IOXGET_32(struct ispsoftc *, u_int32_t *srcptr, u_int32_t dstrval) * * ISP_SWIZZLE_NVRAM_WORD(struct ispsoftc *, u_int16_t *) * ISP_SWIZZLE_NVRAM_LONG(struct ispsoftc *, u_int32_t *) * ISP_SWAP16(struct ispsoftc *, u_int16_t srcval) * ISP_SWAP32(struct ispsoftc *, u_int32_t srcval) */ #endif /* _ISPVAR_H */