Index: stable/9/sys/conf/NOTES =================================================================== --- stable/9/sys/conf/NOTES (revision 237207) +++ stable/9/sys/conf/NOTES (revision 237208) @@ -1,2972 +1,2972 @@ # $FreeBSD$ # # NOTES -- Lines that can be cut/pasted into kernel and hints configs. # # Lines that begin with 'device', 'options', 'machine', 'ident', 'maxusers', # 'makeoptions', 'hints', etc. go into the kernel configuration that you # run config(8) with. # # Lines that begin with 'hint.' are NOT for config(8), they go into your # hints file. See /boot/device.hints and/or the 'hints' config(8) directive. # # Please use ``make LINT'' to create an old-style LINT file if you want to # do kernel test-builds. # # This file contains machine independent kernel configuration notes. For # machine dependent notes, look in /sys//conf/NOTES. # # # NOTES conventions and style guide: # # Large block comments should begin and end with a line containing only a # comment character. # # To describe a particular object, a block comment (if it exists) should # come first. Next should come device, options, and hints lines in that # order. All device and option lines must be described by a comment that # doesn't just expand the device or option name. Use only a concise # comment on the same line if possible. Very detailed descriptions of # devices and subsystems belong in man pages. # # A space followed by a tab separates 'options' from an option name. Two # spaces followed by a tab separate 'device' from a device name. Comments # after an option or device should use one space after the comment character. # To comment out a negative option that disables code and thus should not be # enabled for LINT builds, precede 'options' with "#!". # # # This is the ``identification'' of the kernel. Usually this should # be the same as the name of your kernel. # ident LINT # # The `maxusers' parameter controls the static sizing of a number of # internal system tables by a formula defined in subr_param.c. # Omitting this parameter or setting it to 0 will cause the system to # auto-size based on physical memory. # maxusers 10 # To statically compile in device wiring instead of /boot/device.hints #hints "LINT.hints" # Default places to look for devices. # Use the following to compile in values accessible to the kernel # through getenv() (or kenv(1) in userland). The format of the file # is 'variable=value', see kenv(1) # #env "LINT.env" # # The `makeoptions' parameter allows variables to be passed to the # generated Makefile in the build area. # # CONF_CFLAGS gives some extra compiler flags that are added to ${CFLAGS} # after most other flags. Here we use it to inhibit use of non-optimal # gcc built-in functions (e.g., memcmp). # # DEBUG happens to be magic. # The following is equivalent to 'config -g KERNELNAME' and creates # 'kernel.debug' compiled with -g debugging as well as a normal # 'kernel'. Use 'make install.debug' to install the debug kernel # but that isn't normally necessary as the debug symbols are not loaded # by the kernel and are not useful there anyway. # # KERNEL can be overridden so that you can change the default name of your # kernel. # # MODULES_OVERRIDE can be used to limit modules built to a specific list. # makeoptions CONF_CFLAGS=-fno-builtin #Don't allow use of memcmp, etc. #makeoptions DEBUG=-g #Build kernel with gdb(1) debug symbols #makeoptions KERNEL=foo #Build kernel "foo" and install "/foo" # Only build ext2fs module plus those parts of the sound system I need. #makeoptions MODULES_OVERRIDE="ext2fs sound/sound sound/driver/maestro3" makeoptions DESTDIR=/tmp # # FreeBSD processes are subject to certain limits to their consumption # of system resources. See getrlimit(2) for more details. Each # resource limit has two values, a "soft" limit and a "hard" limit. # The soft limits can be modified during normal system operation, but # the hard limits are set at boot time. Their default values are # in sys//include/vmparam.h. There are two ways to change them: # # 1. Set the values at kernel build time. The options below are one # way to allow that limit to grow to 1GB. They can be increased # further by changing the parameters: # # 2. In /boot/loader.conf, set the tunables kern.maxswzone, # kern.maxbcache, kern.maxtsiz, kern.dfldsiz, kern.maxdsiz, # kern.dflssiz, kern.maxssiz and kern.sgrowsiz. # # The options in /boot/loader.conf override anything in the kernel # configuration file. See the function init_param1 in # sys/kern/subr_param.c for more details. # options MAXDSIZ=(1024UL*1024*1024) options MAXSSIZ=(128UL*1024*1024) options DFLDSIZ=(1024UL*1024*1024) # # BLKDEV_IOSIZE sets the default block size used in user block # device I/O. Note that this value will be overridden by the label # when specifying a block device from a label with a non-0 # partition blocksize. The default is PAGE_SIZE. # options BLKDEV_IOSIZE=8192 # # MAXPHYS and DFLTPHYS # # These are the maximal and safe 'raw' I/O block device access sizes. # Reads and writes will be split into MAXPHYS chunks for known good # devices and DFLTPHYS for the rest. Some applications have better # performance with larger raw I/O access sizes. Note that certain VM # parameters are derived from these values and making them too large # can make an an unbootable kernel. # # The defaults are 64K and 128K respectively. options DFLTPHYS=(64*1024) options MAXPHYS=(128*1024) # This allows you to actually store this configuration file into # the kernel binary itself. See config(8) for more details. # options INCLUDE_CONFIG_FILE # Include this file in kernel options GEOM_AES # Don't use, use GEOM_BDE options GEOM_BDE # Disk encryption. options GEOM_BSD # BSD disklabels options GEOM_CACHE # Disk cache. options GEOM_CONCAT # Disk concatenation. options GEOM_ELI # Disk encryption. options GEOM_FOX # Redundant path mitigation options GEOM_GATE # Userland services. options GEOM_JOURNAL # Journaling. options GEOM_LABEL # Providers labelization. options GEOM_LINUX_LVM # Linux LVM2 volumes options GEOM_MBR # DOS/MBR partitioning options GEOM_MIRROR # Disk mirroring. options GEOM_MULTIPATH # Disk multipath options GEOM_NOP # Test class. options GEOM_PART_APM # Apple partitioning options GEOM_PART_BSD # BSD disklabel options GEOM_PART_EBR # Extended Boot Records options GEOM_PART_EBR_COMPAT # Backward compatible partition names options GEOM_PART_GPT # GPT partitioning options GEOM_PART_LDM # Logical Disk Manager options GEOM_PART_MBR # MBR partitioning options GEOM_PART_PC98 # PC-9800 disk partitioning options GEOM_PART_VTOC8 # SMI VTOC8 disk label options GEOM_PC98 # NEC PC9800 partitioning options GEOM_RAID # Soft RAID functionality. options GEOM_RAID3 # RAID3 functionality. options GEOM_SHSEC # Shared secret. options GEOM_STRIPE # Disk striping. options GEOM_SUNLABEL # Sun/Solaris partitioning options GEOM_UZIP # Read-only compressed disks options GEOM_VIRSTOR # Virtual storage. options GEOM_VOL # Volume names from UFS superblock options GEOM_ZERO # Performance testing helper. # # The root device and filesystem type can be compiled in; # this provides a fallback option if the root device cannot # be correctly guessed by the bootstrap code, or an override if # the RB_DFLTROOT flag (-r) is specified when booting the kernel. # options ROOTDEVNAME=\"ufs:da0s2e\" ##################################################################### # Scheduler options: # # Specifying one of SCHED_4BSD or SCHED_ULE is mandatory. These options # select which scheduler is compiled in. # # SCHED_4BSD is the historical, proven, BSD scheduler. It has a global run # queue and no CPU affinity which makes it suboptimal for SMP. It has very # good interactivity and priority selection. # # SCHED_ULE provides significant performance advantages over 4BSD on many # workloads on SMP machines. It supports cpu-affinity, per-cpu runqueues # and scheduler locks. It also has a stronger notion of interactivity # which leads to better responsiveness even on uniprocessor machines. This # is the default scheduler. # # SCHED_STATS is a debugging option which keeps some stats in the sysctl # tree at 'kern.sched.stats' and is useful for debugging scheduling decisions. # options SCHED_4BSD options SCHED_STATS #options SCHED_ULE ##################################################################### # SMP OPTIONS: # # SMP enables building of a Symmetric MultiProcessor Kernel. # Mandatory: options SMP # Symmetric MultiProcessor Kernel # MAXCPU defines the maximum number of CPUs that can boot in the system. # A default value should be already present, for every architecture. options MAXCPU=32 # ADAPTIVE_MUTEXES changes the behavior of blocking mutexes to spin # if the thread that currently owns the mutex is executing on another # CPU. This behaviour is enabled by default, so this option can be used # to disable it. options NO_ADAPTIVE_MUTEXES # ADAPTIVE_RWLOCKS changes the behavior of reader/writer locks to spin # if the thread that currently owns the rwlock is executing on another # CPU. This behaviour is enabled by default, so this option can be used # to disable it. options NO_ADAPTIVE_RWLOCKS # ADAPTIVE_SX changes the behavior of sx locks to spin if the thread that # currently owns the sx lock is executing on another CPU. # This behaviour is enabled by default, so this option can be used to # disable it. options NO_ADAPTIVE_SX # MUTEX_NOINLINE forces mutex operations to call functions to perform each # operation rather than inlining the simple cases. This can be used to # shrink the size of the kernel text segment. Note that this behavior is # already implied by the INVARIANT_SUPPORT, INVARIANTS, KTR, LOCK_PROFILING, # and WITNESS options. options MUTEX_NOINLINE # RWLOCK_NOINLINE forces rwlock operations to call functions to perform each # operation rather than inlining the simple cases. This can be used to # shrink the size of the kernel text segment. Note that this behavior is # already implied by the INVARIANT_SUPPORT, INVARIANTS, KTR, LOCK_PROFILING, # and WITNESS options. options RWLOCK_NOINLINE # SX_NOINLINE forces sx lock operations to call functions to perform each # operation rather than inlining the simple cases. This can be used to # shrink the size of the kernel text segment. Note that this behavior is # already implied by the INVARIANT_SUPPORT, INVARIANTS, KTR, LOCK_PROFILING, # and WITNESS options. options SX_NOINLINE # SMP Debugging Options: # # PREEMPTION allows the threads that are in the kernel to be preempted by # higher priority [interrupt] threads. It helps with interactivity # and allows interrupt threads to run sooner rather than waiting. # WARNING! Only tested on amd64 and i386. # FULL_PREEMPTION instructs the kernel to preempt non-realtime kernel # threads. Its sole use is to expose race conditions and other # bugs during development. Enabling this option will reduce # performance and increase the frequency of kernel panics by # design. If you aren't sure that you need it then you don't. # Relies on the PREEMPTION option. DON'T TURN THIS ON. # MUTEX_DEBUG enables various extra assertions in the mutex code. # SLEEPQUEUE_PROFILING enables rudimentary profiling of the hash table # used to hold active sleep queues as well as sleep wait message # frequency. # TURNSTILE_PROFILING enables rudimentary profiling of the hash table # used to hold active lock queues. # UMTX_PROFILING enables rudimentary profiling of the hash table used to hold active lock queues. # WITNESS enables the witness code which detects deadlocks and cycles # during locking operations. # WITNESS_KDB causes the witness code to drop into the kernel debugger if # a lock hierarchy violation occurs or if locks are held when going to # sleep. # WITNESS_SKIPSPIN disables the witness checks on spin mutexes. options PREEMPTION options FULL_PREEMPTION options MUTEX_DEBUG options WITNESS options WITNESS_KDB options WITNESS_SKIPSPIN # LOCK_PROFILING - Profiling locks. See LOCK_PROFILING(9) for details. options LOCK_PROFILING # Set the number of buffers and the hash size. The hash size MUST be larger # than the number of buffers. Hash size should be prime. options MPROF_BUFFERS="1536" options MPROF_HASH_SIZE="1543" # Profiling for internal hash tables. options SLEEPQUEUE_PROFILING options TURNSTILE_PROFILING options UMTX_PROFILING ##################################################################### # COMPATIBILITY OPTIONS # # Implement system calls compatible with 4.3BSD and older versions of # FreeBSD. You probably do NOT want to remove this as much current code # still relies on the 4.3 emulation. Note that some architectures that # are supported by FreeBSD do not include support for certain important # aspects of this compatibility option, namely those related to the # signal delivery mechanism. # options COMPAT_43 # Old tty interface. options COMPAT_43TTY # Note that as a general rule, COMPAT_FREEBSD depends on # COMPAT_FREEBSD, COMPAT_FREEBSD, etc. # Enable FreeBSD4 compatibility syscalls options COMPAT_FREEBSD4 # Enable FreeBSD5 compatibility syscalls options COMPAT_FREEBSD5 # Enable FreeBSD6 compatibility syscalls options COMPAT_FREEBSD6 # Enable FreeBSD7 compatibility syscalls options COMPAT_FREEBSD7 # # These three options provide support for System V Interface # Definition-style interprocess communication, in the form of shared # memory, semaphores, and message queues, respectively. # options SYSVSHM options SYSVSEM options SYSVMSG ##################################################################### # DEBUGGING OPTIONS # # Compile with kernel debugger related code. # options KDB # # Print a stack trace of the current thread on the console for a panic. # options KDB_TRACE # # Don't enter the debugger for a panic. Intended for unattended operation # where you may want to enter the debugger from the console, but still want # the machine to recover from a panic. # options KDB_UNATTENDED # # Enable the ddb debugger backend. # options DDB # # Print the numerical value of symbols in addition to the symbolic # representation. # options DDB_NUMSYM # # Enable the remote gdb debugger backend. # options GDB # # SYSCTL_DEBUG enables a 'sysctl' debug tree that can be used to dump the # contents of the registered sysctl nodes on the console. It is disabled by # default because it generates excessively verbose console output that can # interfere with serial console operation. # options SYSCTL_DEBUG # # NO_SYSCTL_DESCR omits the sysctl node descriptions to save space in the # resulting kernel. options NO_SYSCTL_DESCR # # MALLOC_DEBUG_MAXZONES enables multiple uma zones for malloc(9) # allocations that are smaller than a page. The purpose is to isolate # different malloc types into hash classes, so that any buffer # overruns or use-after-free will usually only affect memory from # malloc types in that hash class. This is purely a debugging tool; # by varying the hash function and tracking which hash class was # corrupted, the intersection of the hash classes from each instance # will point to a single malloc type that is being misused. At this # point inspection or memguard(9) can be used to catch the offending # code. # options MALLOC_DEBUG_MAXZONES=8 # # DEBUG_MEMGUARD builds and enables memguard(9), a replacement allocator # for the kernel used to detect modify-after-free scenarios. See the # memguard(9) man page for more information on usage. # options DEBUG_MEMGUARD # # DEBUG_REDZONE enables buffer underflows and buffer overflows detection for # malloc(9). # options DEBUG_REDZONE # # KTRACE enables the system-call tracing facility ktrace(2). To be more # SMP-friendly, KTRACE uses a worker thread to process most trace events # asynchronously to the thread generating the event. This requires a # pre-allocated store of objects representing trace events. The # KTRACE_REQUEST_POOL option specifies the initial size of this store. # The size of the pool can be adjusted both at boottime and runtime via # the kern.ktrace_request_pool tunable and sysctl. # options KTRACE #kernel tracing options KTRACE_REQUEST_POOL=101 # # KTR is a kernel tracing facility imported from BSD/OS. It is # enabled with the KTR option. KTR_ENTRIES defines the number of # entries in the circular trace buffer; it must be a power of two. # KTR_COMPILE defines the mask of events to compile into the kernel as # defined by the KTR_* constants in . KTR_MASK defines the # initial value of the ktr_mask variable which determines at runtime # what events to trace. KTR_CPUMASK determines which CPU's log # events, with bit X corresponding to CPU X. The layout of the string # passed as KTR_CPUMASK must match a serie of bitmasks each of them # separated by the ", " characters (ie: # KTR_CPUMASK=("0xAF, 0xFFFFFFFFFFFFFFFF")). KTR_VERBOSE enables # dumping of KTR events to the console by default. This functionality # can be toggled via the debug.ktr_verbose sysctl and defaults to off # if KTR_VERBOSE is not defined. See ktr(4) and ktrdump(8) for details. # options KTR options KTR_ENTRIES=1024 options KTR_COMPILE=(KTR_INTR|KTR_PROC) options KTR_MASK=KTR_INTR options KTR_CPUMASK=("0x3") options KTR_VERBOSE # # ALQ(9) is a facility for the asynchronous queuing of records from the kernel # to a vnode, and is employed by services such as ktr(4) to produce trace # files based on a kernel event stream. Records are written asynchronously # in a worker thread. # options ALQ options KTR_ALQ # # The INVARIANTS option is used in a number of source files to enable # extra sanity checking of internal structures. This support is not # enabled by default because of the extra time it would take to check # for these conditions, which can only occur as a result of # programming errors. # options INVARIANTS # # The INVARIANT_SUPPORT option makes us compile in support for # verifying some of the internal structures. It is a prerequisite for # 'INVARIANTS', as enabling 'INVARIANTS' will make these functions be # called. The intent is that you can set 'INVARIANTS' for single # source files (by changing the source file or specifying it on the # command line) if you have 'INVARIANT_SUPPORT' enabled. Also, if you # wish to build a kernel module with 'INVARIANTS', then adding # 'INVARIANT_SUPPORT' to your kernel will provide all the necessary # infrastructure without the added overhead. # options INVARIANT_SUPPORT # # The DIAGNOSTIC option is used to enable extra debugging information # from some parts of the kernel. As this makes everything more noisy, # it is disabled by default. # options DIAGNOSTIC # # REGRESSION causes optional kernel interfaces necessary only for regression # testing to be enabled. These interfaces may constitute security risks # when enabled, as they permit processes to easily modify aspects of the # run-time environment to reproduce unlikely or unusual (possibly normally # impossible) scenarios. # options REGRESSION # # This option lets some drivers co-exist that can't co-exist in a running # system. This is used to be able to compile all kernel code in one go for # quality assurance purposes (like this file, which the option takes it name # from.) # options COMPILING_LINT # # STACK enables the stack(9) facility, allowing the capture of kernel stack # for the purpose of procinfo(1), etc. stack(9) will also be compiled in # automatically if DDB(4) is compiled into the kernel. # options STACK ##################################################################### # PERFORMANCE MONITORING OPTIONS # # The hwpmc driver that allows the use of in-CPU performance monitoring # counters for performance monitoring. The base kernel needs to be configured # with the 'options' line, while the hwpmc device can be either compiled # in or loaded as a loadable kernel module. # # Additional configuration options may be required on specific architectures, # please see hwpmc(4). device hwpmc # Driver (also a loadable module) options HWPMC_HOOKS # Other necessary kernel hooks ##################################################################### # NETWORKING OPTIONS # # Protocol families # options INET #Internet communications protocols options INET6 #IPv6 communications protocols options ROUTETABLES=2 # max 16. 1 is back compatible. # In order to enable IPSEC you MUST also add device crypto to # your kernel configuration options IPSEC #IP security (requires device crypto) #options IPSEC_DEBUG #debug for IP security # # #DEPRECATED# # Set IPSEC_FILTERTUNNEL to change the default of the sysctl to force packets # coming through a tunnel to be processed by any configured packet filtering # twice. The default is that packets coming out of a tunnel are _not_ processed; # they are assumed trusted. # # IPSEC history is preserved for such packets, and can be filtered # using ipfw(8)'s 'ipsec' keyword, when this option is enabled. # #options IPSEC_FILTERTUNNEL #filter ipsec packets from a tunnel # # Set IPSEC_NAT_T to enable NAT-Traversal support. This enables # optional UDP encapsulation of ESP packets. # options IPSEC_NAT_T #NAT-T support, UDP encap of ESP options IPX #IPX/SPX communications protocols options NCP #NetWare Core protocol options NETATALK #Appletalk communications protocols options NETATALKDEBUG #Appletalk debugging # # SMB/CIFS requester # NETSMB enables support for SMB protocol, it requires LIBMCHAIN and LIBICONV # options. options NETSMB #SMB/CIFS requester # mchain library. It can be either loaded as KLD or compiled into kernel options LIBMCHAIN # libalias library, performing NAT options LIBALIAS # flowtable cache options FLOWTABLE # # SCTP is a NEW transport protocol defined by # RFC2960 updated by RFC3309 and RFC3758.. and # soon to have a new base RFC and many many more # extensions. This release supports all the extensions # including many drafts (most about to become RFC's). # It is the reference implementation of SCTP # and is quite well tested. # # Note YOU MUST have both INET and INET6 defined. # You don't have to enable V6, but SCTP is # dual stacked and so far we have not torn apart # the V6 and V4.. since an association can span # both a V6 and V4 address at the SAME time :-) # options SCTP # There are bunches of options: # this one turns on all sorts of # nastly printing that you can # do. It's all controlled by a # bit mask (settable by socket opt and # by sysctl). Including will not cause # logging until you set the bits.. but it # can be quite verbose.. so without this # option we don't do any of the tests for # bits and prints.. which makes the code run # faster.. if you are not debugging don't use. options SCTP_DEBUG # # This option turns off the CRC32c checksum. Basically, # you will not be able to talk to anyone else who # has not done this. Its more for experimentation to # see how much CPU the CRC32c really takes. Most new # cards for TCP support checksum offload.. so this # option gives you a "view" into what SCTP would be # like with such an offload (which only exists in # high in iSCSI boards so far). With the new # splitting 8's algorithm its not as bad as it used # to be.. but it does speed things up try only # for in a captured lab environment :-) options SCTP_WITH_NO_CSUM # # # All that options after that turn on specific types of # logging. You can monitor CWND growth, flight size # and all sorts of things. Go look at the code and # see. I have used this to produce interesting # charts and graphs as well :-> # # I have not yet committed the tools to get and print # the logs, I will do that eventually .. before then # if you want them send me an email rrs@freebsd.org # You basically must have ktr(4) enabled for these # and you then set the sysctl to turn on/off various # logging bits. Use ktrdump(8) to pull the log and run # it through a display program.. and graphs and other # things too. # options SCTP_LOCK_LOGGING options SCTP_MBUF_LOGGING options SCTP_MBCNT_LOGGING options SCTP_PACKET_LOGGING options SCTP_LTRACE_CHUNKS options SCTP_LTRACE_ERRORS # altq(9). Enable the base part of the hooks with the ALTQ option. # Individual disciplines must be built into the base system and can not be # loaded as modules at this point. ALTQ requires a stable TSC so if yours is # broken or changes with CPU throttling then you must also have the ALTQ_NOPCC # option. options ALTQ options ALTQ_CBQ # Class Based Queueing options ALTQ_RED # Random Early Detection options ALTQ_RIO # RED In/Out options ALTQ_HFSC # Hierarchical Packet Scheduler options ALTQ_CDNR # Traffic conditioner options ALTQ_PRIQ # Priority Queueing options ALTQ_NOPCC # Required if the TSC is unusable options ALTQ_DEBUG # netgraph(4). Enable the base netgraph code with the NETGRAPH option. # Individual node types can be enabled with the corresponding option # listed below; however, this is not strictly necessary as netgraph # will automatically load the corresponding KLD module if the node type # is not already compiled into the kernel. Each type below has a # corresponding man page, e.g., ng_async(8). options NETGRAPH # netgraph(4) system options NETGRAPH_DEBUG # enable extra debugging, this # affects netgraph(4) and nodes # Node types options NETGRAPH_ASYNC options NETGRAPH_ATMLLC options NETGRAPH_ATM_ATMPIF options NETGRAPH_BLUETOOTH # ng_bluetooth(4) options NETGRAPH_BLUETOOTH_BT3C # ng_bt3c(4) options NETGRAPH_BLUETOOTH_HCI # ng_hci(4) options NETGRAPH_BLUETOOTH_L2CAP # ng_l2cap(4) options NETGRAPH_BLUETOOTH_SOCKET # ng_btsocket(4) options NETGRAPH_BLUETOOTH_UBT # ng_ubt(4) options NETGRAPH_BLUETOOTH_UBTBCMFW # ubtbcmfw(4) options NETGRAPH_BPF options NETGRAPH_BRIDGE options NETGRAPH_CAR options NETGRAPH_CISCO options NETGRAPH_DEFLATE options NETGRAPH_DEVICE options NETGRAPH_ECHO options NETGRAPH_EIFACE options NETGRAPH_ETHER options NETGRAPH_FEC options NETGRAPH_FRAME_RELAY options NETGRAPH_GIF options NETGRAPH_GIF_DEMUX options NETGRAPH_HOLE options NETGRAPH_IFACE options NETGRAPH_IP_INPUT options NETGRAPH_IPFW options NETGRAPH_KSOCKET options NETGRAPH_L2TP options NETGRAPH_LMI # MPPC compression requires proprietary files (not included) #options NETGRAPH_MPPC_COMPRESSION options NETGRAPH_MPPC_ENCRYPTION options NETGRAPH_NETFLOW options NETGRAPH_NAT options NETGRAPH_ONE2MANY options NETGRAPH_PATCH options NETGRAPH_PIPE options NETGRAPH_PPP options NETGRAPH_PPPOE options NETGRAPH_PPTPGRE options NETGRAPH_PRED1 options NETGRAPH_RFC1490 options NETGRAPH_SOCKET options NETGRAPH_SPLIT options NETGRAPH_SPPP options NETGRAPH_TAG options NETGRAPH_TCPMSS options NETGRAPH_TEE options NETGRAPH_UI options NETGRAPH_VJC options NETGRAPH_VLAN # NgATM - Netgraph ATM options NGATM_ATM options NGATM_ATMBASE options NGATM_SSCOP options NGATM_SSCFU options NGATM_UNI options NGATM_CCATM device mn # Munich32x/Falc54 Nx64kbit/sec cards. # # Network interfaces: # The `loop' device is MANDATORY when networking is enabled. device loop # The `ether' device provides generic code to handle # Ethernets; it is MANDATORY when an Ethernet device driver is # configured or token-ring is enabled. device ether # The `vlan' device implements the VLAN tagging of Ethernet frames # according to IEEE 802.1Q. device vlan # The `wlan' device provides generic code to support 802.11 # drivers, including host AP mode; it is MANDATORY for the wi, # and ath drivers and will eventually be required by all 802.11 drivers. device wlan options IEEE80211_DEBUG #enable debugging msgs options IEEE80211_AMPDU_AGE #age frames in AMPDU reorder q's options IEEE80211_SUPPORT_MESH #enable 802.11s D3.0 support options IEEE80211_SUPPORT_TDMA #enable TDMA support # The `wlan_wep', `wlan_tkip', and `wlan_ccmp' devices provide # support for WEP, TKIP, and AES-CCMP crypto protocols optionally # used with 802.11 devices that depend on the `wlan' module. device wlan_wep device wlan_ccmp device wlan_tkip # The `wlan_xauth' device provides support for external (i.e. user-mode) # authenticators for use with 802.11 drivers that use the `wlan' # module and support 802.1x and/or WPA security protocols. device wlan_xauth # The `wlan_acl' device provides a MAC-based access control mechanism # for use with 802.11 drivers operating in ap mode and using the # `wlan' module. # The 'wlan_amrr' device provides AMRR transmit rate control algorithm device wlan_acl device wlan_amrr # Generic TokenRing device token # The `fddi' device provides generic code to support FDDI. device fddi # The `arcnet' device provides generic code to support Arcnet. device arcnet # The `sppp' device serves a similar role for certain types # of synchronous PPP links (like `cx', `ar'). device sppp # The `bpf' device enables the Berkeley Packet Filter. Be # aware of the legal and administrative consequences of enabling this # option. DHCP requires bpf. device bpf # The `netmap' device implements memory-mapped access to network # devices from userspace, enabling wire-speed packet capture and # generation even at 10Gbit/s. Requires support in the device # driver. Supported drivers are ixgbe, e1000, re. device netmap # The `disc' device implements a minimal network interface, # which throws away all packets sent and never receives any. It is # included for testing and benchmarking purposes. device disc # The `epair' device implements a virtual back-to-back connected Ethernet # like interface pair. device epair # The `edsc' device implements a minimal Ethernet interface, # which discards all packets sent and receives none. device edsc # The `tap' device is a pty-like virtual Ethernet interface device tap # The `tun' device implements (user-)ppp and nos-tun(8) device tun # The `gif' device implements IPv6 over IP4 tunneling, # IPv4 over IPv6 tunneling, IPv4 over IPv4 tunneling and # IPv6 over IPv6 tunneling. # The `gre' device implements two types of IP4 over IP4 tunneling: # GRE and MOBILE, as specified in the RFC1701 and RFC2004. # The XBONEHACK option allows the same pair of addresses to be configured on # multiple gif interfaces. device gif device gre options XBONEHACK # The `faith' device captures packets sent to it and diverts them # to the IPv4/IPv6 translation daemon. # The `stf' device implements 6to4 encapsulation. device faith device stf # The `ef' device provides support for multiple ethernet frame types # specified via ETHER_* options. See ef(4) for details. device ef options ETHER_II # enable Ethernet_II frame options ETHER_8023 # enable Ethernet_802.3 (Novell) frame options ETHER_8022 # enable Ethernet_802.2 frame options ETHER_SNAP # enable Ethernet_802.2/SNAP frame # The pf packet filter consists of three devices: # The `pf' device provides /dev/pf and the firewall code itself. # The `pflog' device provides the pflog0 interface which logs packets. # The `pfsync' device provides the pfsync0 interface used for # synchronization of firewall state tables (over the net). device pf device pflog device pfsync # Bridge interface. device if_bridge # Common Address Redundancy Protocol. See carp(4) for more details. device carp # IPsec interface. device enc # Link aggregation interface. device lagg # # Internet family options: # # MROUTING enables the kernel multicast packet forwarder, which works # with mrouted and XORP. # # IPFIREWALL enables support for IP firewall construction, in # conjunction with the `ipfw' program. IPFIREWALL_VERBOSE sends # logged packets to the system logger. IPFIREWALL_VERBOSE_LIMIT # limits the number of times a matching entry can be logged. # # WARNING: IPFIREWALL defaults to a policy of "deny ip from any to any" # and if you do not add other rules during startup to allow access, # YOU WILL LOCK YOURSELF OUT. It is suggested that you set firewall_type=open # in /etc/rc.conf when first enabling this feature, then refining the # firewall rules in /etc/rc.firewall after you've tested that the new kernel # feature works properly. # # IPFIREWALL_DEFAULT_TO_ACCEPT causes the default rule (at boot) to # allow everything. Use with care, if a cracker can crash your # firewall machine, they can get to your protected machines. However, # if you are using it as an as-needed filter for specific problems as # they arise, then this may be for you. Changing the default to 'allow' # means that you won't get stuck if the kernel and /sbin/ipfw binary get # out of sync. # # IPDIVERT enables the divert IP sockets, used by ``ipfw divert''. It # depends on IPFIREWALL if compiled into the kernel. # # IPFIREWALL_FORWARD enables changing of the packet destination either # to do some sort of policy routing or transparent proxying. Used by # ``ipfw forward''. All redirections apply to locally generated # packets too. Because of this great care is required when # crafting the ruleset. # # IPFIREWALL_NAT adds support for in kernel nat in ipfw, and it requires # LIBALIAS. # # IPSTEALTH enables code to support stealth forwarding (i.e., forwarding # packets without touching the TTL). This can be useful to hide firewalls # from traceroute and similar tools. # # TCPDEBUG enables code which keeps traces of the TCP state machine # for sockets with the SO_DEBUG option set, which can then be examined # using the trpt(8) utility. # options MROUTING # Multicast routing options IPFIREWALL #firewall options IPFIREWALL_VERBOSE #enable logging to syslogd(8) options IPFIREWALL_VERBOSE_LIMIT=100 #limit verbosity options IPFIREWALL_DEFAULT_TO_ACCEPT #allow everything by default options IPFIREWALL_FORWARD #packet destination changes options IPFIREWALL_NAT #ipfw kernel nat support options IPDIVERT #divert sockets options IPFILTER #ipfilter support options IPFILTER_LOG #ipfilter logging options IPFILTER_LOOKUP #ipfilter pools options IPFILTER_DEFAULT_BLOCK #block all packets by default options IPSTEALTH #support for stealth forwarding options TCPDEBUG # The MBUF_STRESS_TEST option enables options which create # various random failures / extreme cases related to mbuf # functions. See mbuf(9) for a list of available test cases. # MBUF_PROFILING enables code to profile the mbuf chains # exiting the system (via participating interfaces) and # return a logarithmic histogram of monitored parameters # (e.g. packet size, wasted space, number of mbufs in chain). options MBUF_STRESS_TEST options MBUF_PROFILING # Statically link in accept filters options ACCEPT_FILTER_DATA options ACCEPT_FILTER_DNS options ACCEPT_FILTER_HTTP # TCP_SIGNATURE adds support for RFC 2385 (TCP-MD5) digests. These are # carried in TCP option 19. This option is commonly used to protect # TCP sessions (e.g. BGP) where IPSEC is not available nor desirable. # This is enabled on a per-socket basis using the TCP_MD5SIG socket option. # This requires the use of 'device crypto', 'options IPSEC' # or 'device cryptodev'. options TCP_SIGNATURE #include support for RFC 2385 # DUMMYNET enables the "dummynet" bandwidth limiter. You need IPFIREWALL # as well. See dummynet(4) and ipfw(8) for more info. When you run # DUMMYNET it is advisable to also have at least "options HZ=1000" to achieve # a smooth scheduling of the traffic. options DUMMYNET # Zero copy sockets support. This enables "zero copy" for sending and # receiving data via a socket. The send side works for any type of NIC, # the receive side only works for NICs that support MTUs greater than the # page size of your architecture and that support header splitting. See # zero_copy(9) for more details. options ZERO_COPY_SOCKETS ##################################################################### # FILESYSTEM OPTIONS # # Only the root filesystem needs to be statically compiled or preloaded # as module; everything else will be automatically loaded at mount # time. Some people still prefer to statically compile other # filesystems as well. # # NB: The PORTAL filesystem is known to be buggy, and WILL panic your # system if you attempt to do anything with it. It is included here # as an incentive for some enterprising soul to sit down and fix it. # The UNION filesystem was known to be buggy in the past. It is now # being actively maintained, although there are still some issues being # resolved. # # One of these is mandatory: options FFS #Fast filesystem options NFSCLIENT #Network File System client # The rest are optional: options CD9660 #ISO 9660 filesystem options FDESCFS #File descriptor filesystem options HPFS #OS/2 File system options MSDOSFS #MS DOS File System (FAT, FAT32) options NFSSERVER #Network File System server options NFSLOCKD #Network Lock Manager options NFSCL #experimental NFS client with NFSv4 options NFSD #experimental NFS server with NFSv4 options KGSSAPI #Kernel GSSAPI implementation # NT File System. Read-mostly, see mount_ntfs(8) for details. # For a full read-write NTFS support consider sysutils/fusefs-ntfs # port/package. options NTFS options NULLFS #NULL filesystem # Broken (depends on NCP): #options NWFS #NetWare filesystem options PORTALFS #Portal filesystem options PROCFS #Process filesystem (requires PSEUDOFS) options PSEUDOFS #Pseudo-filesystem framework options PSEUDOFS_TRACE #Debugging support for PSEUDOFS options SMBFS #SMB/CIFS filesystem options TMPFS #Efficient memory filesystem options UDF #Universal Disk Format options UNIONFS #Union filesystem # The xFS_ROOT options REQUIRE the associated ``options xFS'' options NFS_ROOT #NFS usable as root device # Soft updates is a technique for improving filesystem speed and # making abrupt shutdown less risky. # options SOFTUPDATES # Extended attributes allow additional data to be associated with files, # and is used for ACLs, Capabilities, and MAC labels. # See src/sys/ufs/ufs/README.extattr for more information. options UFS_EXTATTR options UFS_EXTATTR_AUTOSTART # Access Control List support for UFS filesystems. The current ACL # implementation requires extended attribute support, UFS_EXTATTR, # for the underlying filesystem. # See src/sys/ufs/ufs/README.acls for more information. options UFS_ACL # Directory hashing improves the speed of operations on very large # directories at the expense of some memory. options UFS_DIRHASH # Gjournal-based UFS journaling support. options UFS_GJOURNAL # Make space in the kernel for a root filesystem on a md device. # Define to the number of kilobytes to reserve for the filesystem. options MD_ROOT_SIZE=10 # Make the md device a potential root device, either with preloaded # images of type mfs_root or md_root. options MD_ROOT # Disk quotas are supported when this option is enabled. options QUOTA #enable disk quotas # If you are running a machine just as a fileserver for PC and MAC # users, using SAMBA or Netatalk, you may consider setting this option # and keeping all those users' directories on a filesystem that is # mounted with the suiddir option. This gives new files the same # ownership as the directory (similar to group). It's a security hole # if you let these users run programs, so confine it to file-servers # (but it'll save you lots of headaches in those cases). Root owned # directories are exempt and X bits are cleared. The suid bit must be # set on the directory as well; see chmod(1). PC owners can't see/set # ownerships so they keep getting their toes trodden on. This saves # you all the support calls as the filesystem it's used on will act as # they expect: "It's my dir so it must be my file". # options SUIDDIR # NFS options: options NFS_MINATTRTIMO=3 # VREG attrib cache timeout in sec options NFS_MAXATTRTIMO=60 options NFS_MINDIRATTRTIMO=30 # VDIR attrib cache timeout in sec options NFS_MAXDIRATTRTIMO=60 options NFS_GATHERDELAY=10 # Default write gather delay (msec) options NFS_WDELAYHASHSIZ=16 # and with this options NFS_DEBUG # Enable NFS Debugging # Coda stuff: options CODA #CODA filesystem. device vcoda #coda minicache <-> venus comm. # Use the old Coda 5.x venus<->kernel interface instead of the new # realms-aware 6.x protocol. #options CODA_COMPAT_5 # # Add support for the EXT2FS filesystem of Linux fame. Be a bit # careful with this - the ext2fs code has a tendency to lag behind # changes and not be exercised very much, so mounting read/write could # be dangerous (and even mounting read only could result in panics.) # options EXT2FS # # Add support for the ReiserFS filesystem (used in Linux). Currently, # this is limited to read-only access. # options REISERFS # # Add support for the SGI XFS filesystem. Currently, # this is limited to read-only access. # options XFS # Use real implementations of the aio_* system calls. There are numerous # stability and security issues in the current aio code that make it # unsuitable for inclusion on machines with untrusted local users. options VFS_AIO # Cryptographically secure random number generator; /dev/random device random # The system memory devices; /dev/mem, /dev/kmem device mem # The kernel symbol table device; /dev/ksyms device ksyms # Optional character code conversion support with LIBICONV. # Each option requires their base file system and LIBICONV. options CD9660_ICONV options MSDOSFS_ICONV options NTFS_ICONV options UDF_ICONV ##################################################################### # POSIX P1003.1B # Real time extensions added in the 1993 POSIX # _KPOSIX_PRIORITY_SCHEDULING: Build in _POSIX_PRIORITY_SCHEDULING options _KPOSIX_PRIORITY_SCHEDULING # p1003_1b_semaphores are very experimental, # user should be ready to assist in debugging if problems arise. options P1003_1B_SEMAPHORES # POSIX message queue options P1003_1B_MQUEUE ##################################################################### # SECURITY POLICY PARAMETERS # Support for BSM audit options AUDIT # Support for Mandatory Access Control (MAC): options MAC options MAC_BIBA options MAC_BSDEXTENDED options MAC_IFOFF options MAC_LOMAC options MAC_MLS options MAC_NONE options MAC_PARTITION options MAC_PORTACL options MAC_SEEOTHERUIDS options MAC_STUB options MAC_TEST # Support for Capsicum options CAPABILITIES # fine-grained rights on file descriptors options CAPABILITY_MODE # sandboxes with no global namespace access # Support for process descriptors options PROCDESC ##################################################################### # CLOCK OPTIONS # The granularity of operation is controlled by the kernel option HZ whose # default value (1000 on most architectures) means a granularity of 1ms # (1s/HZ). Historically, the default was 100, but finer granularity is # required for DUMMYNET and other systems on modern hardware. There are # reasonable arguments that HZ should, in fact, be 100 still; consider, # that reducing the granularity too much might cause excessive overhead in # clock interrupt processing, potentially causing ticks to be missed and thus # actually reducing the accuracy of operation. options HZ=100 # Enable support for the kernel PLL to use an external PPS signal, # under supervision of [x]ntpd(8) # More info in ntpd documentation: http://www.eecis.udel.edu/~ntp options PPS_SYNC ##################################################################### # SCSI DEVICES # SCSI DEVICE CONFIGURATION # The SCSI subsystem consists of the `base' SCSI code, a number of # high-level SCSI device `type' drivers, and the low-level host-adapter # device drivers. The host adapters are listed in the ISA and PCI # device configuration sections below. # # It is possible to wire down your SCSI devices so that a given bus, # target, and LUN always come on line as the same device unit. In # earlier versions the unit numbers were assigned in the order that # the devices were probed on the SCSI bus. This means that if you # removed a disk drive, you may have had to rewrite your /etc/fstab # file, and also that you had to be careful when adding a new disk # as it may have been probed earlier and moved your device configuration # around. (See also option GEOM_VOL for a different solution to this # problem.) # This old behavior is maintained as the default behavior. The unit # assignment begins with the first non-wired down unit for a device # type. For example, if you wire a disk as "da3" then the first # non-wired disk will be assigned da4. # The syntax for wiring down devices is: hint.scbus.0.at="ahc0" hint.scbus.1.at="ahc1" hint.scbus.1.bus="0" hint.scbus.3.at="ahc2" hint.scbus.3.bus="0" hint.scbus.2.at="ahc2" hint.scbus.2.bus="1" hint.da.0.at="scbus0" hint.da.0.target="0" hint.da.0.unit="0" hint.da.1.at="scbus3" hint.da.1.target="1" hint.da.2.at="scbus2" hint.da.2.target="3" hint.sa.1.at="scbus1" hint.sa.1.target="6" # "units" (SCSI logical unit number) that are not specified are # treated as if specified as LUN 0. # All SCSI devices allocate as many units as are required. # The ch driver drives SCSI Media Changer ("jukebox") devices. # # The da driver drives SCSI Direct Access ("disk") and Optical Media # ("WORM") devices. # # The sa driver drives SCSI Sequential Access ("tape") devices. # # The cd driver drives SCSI Read Only Direct Access ("cd") devices. # # The ses driver drives SCSI Environment Services ("ses") and # SAF-TE ("SCSI Accessible Fault-Tolerant Enclosure") devices. # # The pt driver drives SCSI Processor devices. # # The sg driver provides a passthrough API that is compatible with the # Linux SG driver. It will work in conjunction with the COMPAT_LINUX # option to run linux SG apps. It can also stand on its own and provide # source level API compatiblity for porting apps to FreeBSD. # # Target Mode support is provided here but also requires that a SIM # (SCSI Host Adapter Driver) provide support as well. # # The targ driver provides target mode support as a Processor type device. # It exists to give the minimal context necessary to respond to Inquiry # commands. There is a sample user application that shows how the rest # of the command support might be done in /usr/share/examples/scsi_target. # # The targbh driver provides target mode support and exists to respond # to incoming commands that do not otherwise have a logical unit assigned # to them. # # The "unknown" device (uk? in pre-2.0.5) is now part of the base SCSI # configuration as the "pass" driver. device scbus #base SCSI code device ch #SCSI media changers device da #SCSI direct access devices (aka disks) device sa #SCSI tapes device cd #SCSI CD-ROMs device ses #SCSI Environmental Services (and SAF-TE) device pt #SCSI processor device targ #SCSI Target Mode Code device targbh #SCSI Target Mode Blackhole Device device pass #CAM passthrough driver device sg #Linux SCSI passthrough device ctl #CAM Target Layer # CAM OPTIONS: # debugging options: # -- NOTE -- If you specify one of the bus/target/lun options, you must # specify them all! # CAMDEBUG: When defined enables debugging macros # CAM_DEBUG_BUS: Debug the given bus. Use -1 to debug all busses. # CAM_DEBUG_TARGET: Debug the given target. Use -1 to debug all targets. # CAM_DEBUG_LUN: Debug the given lun. Use -1 to debug all luns. # CAM_DEBUG_FLAGS: OR together CAM_DEBUG_INFO, CAM_DEBUG_TRACE, # CAM_DEBUG_SUBTRACE, and CAM_DEBUG_CDB # # CAM_MAX_HIGHPOWER: Maximum number of concurrent high power (start unit) cmds # SCSI_NO_SENSE_STRINGS: When defined disables sense descriptions # SCSI_NO_OP_STRINGS: When defined disables opcode descriptions # SCSI_DELAY: The number of MILLISECONDS to freeze the SIM (scsi adapter) # queue after a bus reset, and the number of milliseconds to # freeze the device queue after a bus device reset. This # can be changed at boot and runtime with the # kern.cam.scsi_delay tunable/sysctl. options CAMDEBUG options CAM_DEBUG_BUS=-1 options CAM_DEBUG_TARGET=-1 options CAM_DEBUG_LUN=-1 options CAM_DEBUG_FLAGS=(CAM_DEBUG_INFO|CAM_DEBUG_TRACE|CAM_DEBUG_CDB) options CAM_MAX_HIGHPOWER=4 options SCSI_NO_SENSE_STRINGS options SCSI_NO_OP_STRINGS options SCSI_DELAY=5000 # Be pessimistic about Joe SCSI device # Options for the CAM CDROM driver: # CHANGER_MIN_BUSY_SECONDS: Guaranteed minimum time quantum for a changer LUN # CHANGER_MAX_BUSY_SECONDS: Maximum time quantum per changer LUN, only # enforced if there is I/O waiting for another LUN # The compiled in defaults for these variables are 2 and 10 seconds, # respectively. # # These can also be changed on the fly with the following sysctl variables: # kern.cam.cd.changer.min_busy_seconds # kern.cam.cd.changer.max_busy_seconds # options CHANGER_MIN_BUSY_SECONDS=2 options CHANGER_MAX_BUSY_SECONDS=10 # Options for the CAM sequential access driver: # SA_IO_TIMEOUT: Timeout for read/write/wfm operations, in minutes # SA_SPACE_TIMEOUT: Timeout for space operations, in minutes # SA_REWIND_TIMEOUT: Timeout for rewind operations, in minutes # SA_ERASE_TIMEOUT: Timeout for erase operations, in minutes # SA_1FM_AT_EOD: Default to model which only has a default one filemark at EOT. options SA_IO_TIMEOUT=4 options SA_SPACE_TIMEOUT=60 options SA_REWIND_TIMEOUT=(2*60) options SA_ERASE_TIMEOUT=(4*60) options SA_1FM_AT_EOD # Optional timeout for the CAM processor target (pt) device # This is specified in seconds. The default is 60 seconds. options SCSI_PT_DEFAULT_TIMEOUT=60 # Optional enable of doing SES passthrough on other devices (e.g., disks) # # Normally disabled because a lot of newer SCSI disks report themselves # as having SES capabilities, but this can then clot up attempts to build # a topology with the SES device that's on the box these drives are in.... options SES_ENABLE_PASSTHROUGH ##################################################################### # MISCELLANEOUS DEVICES AND OPTIONS device pty #BSD-style compatibility pseudo ttys device nmdm #back-to-back tty devices device md #Memory/malloc disk device snp #Snoop device - to look at pty/vty/etc.. device ccd #Concatenated disk driver device firmware #firmware(9) support # Kernel side iconv library options LIBICONV # Size of the kernel message buffer. Should be N * pagesize. options MSGBUF_SIZE=40960 ##################################################################### # HARDWARE DEVICE CONFIGURATION # For ISA the required hints are listed. # EISA, MCA, PCI, CardBus, SD/MMC and pccard are self identifying buses, so # no hints are needed. # # Mandatory devices: # # These options are valid for other keyboard drivers as well. options KBD_DISABLE_KEYMAP_LOAD # refuse to load a keymap options KBD_INSTALL_CDEV # install a CDEV entry in /dev options FB_DEBUG # Frame buffer debugging device splash # Splash screen and screen saver support # Various screen savers. device blank_saver device daemon_saver device dragon_saver device fade_saver device fire_saver device green_saver device logo_saver device rain_saver device snake_saver device star_saver device warp_saver # The syscons console driver (SCO color console compatible). device sc hint.sc.0.at="isa" options MAXCONS=16 # number of virtual consoles options SC_ALT_MOUSE_IMAGE # simplified mouse cursor in text mode options SC_DFLT_FONT # compile font in makeoptions SC_DFLT_FONT=cp850 options SC_DISABLE_KDBKEY # disable `debug' key options SC_DISABLE_REBOOT # disable reboot key sequence options SC_HISTORY_SIZE=200 # number of history buffer lines options SC_MOUSE_CHAR=0x3 # char code for text mode mouse cursor options SC_PIXEL_MODE # add support for the raster text mode # The following options will let you change the default colors of syscons. options SC_NORM_ATTR=(FG_GREEN|BG_BLACK) options SC_NORM_REV_ATTR=(FG_YELLOW|BG_GREEN) options SC_KERNEL_CONS_ATTR=(FG_RED|BG_BLACK) options SC_KERNEL_CONS_REV_ATTR=(FG_BLACK|BG_RED) # The following options will let you change the default behaviour of # cut-n-paste feature options SC_CUT_SPACES2TABS # convert leading spaces into tabs options SC_CUT_SEPCHARS=\"x09\" # set of characters that delimit words # (default is single space - \"x20\") # If you have a two button mouse, you may want to add the following option # to use the right button of the mouse to paste text. options SC_TWOBUTTON_MOUSE # You can selectively disable features in syscons. options SC_NO_CUTPASTE options SC_NO_FONT_LOADING options SC_NO_HISTORY options SC_NO_MODE_CHANGE options SC_NO_SYSMOUSE options SC_NO_SUSPEND_VTYSWITCH # `flags' for sc # 0x80 Put the video card in the VESA 800x600 dots, 16 color mode # 0x100 Probe for a keyboard device periodically if one is not present # Enable experimental features of the syscons terminal emulator (teken). options TEKEN_CONS25 # cons25-style terminal emulation options TEKEN_UTF8 # UTF-8 output handling # # Optional devices: # # # SCSI host adapters: # # adv: All Narrow SCSI bus AdvanSys controllers. # adw: Second Generation AdvanSys controllers including the ADV940UW. # aha: Adaptec 154x/1535/1640 # ahb: Adaptec 174x EISA controllers # ahc: Adaptec 274x/284x/2910/293x/294x/394x/3950x/3960x/398X/4944/ # 19160x/29160x, aic7770/aic78xx # ahd: Adaptec 29320/39320 Controllers. # aic: Adaptec 6260/6360, APA-1460 (PC Card), NEC PC9801-100 (C-BUS) # amd: Support for the AMD 53C974 SCSI host adapter chip as found on devices # such as the Tekram DC-390(T). # bt: Most Buslogic controllers: including BT-445, BT-54x, BT-64x, BT-74x, # BT-75x, BT-946, BT-948, BT-956, BT-958, SDC3211B, SDC3211F, SDC3222F # esp: Emulex ESP, NCR 53C9x and QLogic FAS families based controllers # including the AMD Am53C974 (found on devices such as the Tekram # DC-390(T)) and the Sun ESP and FAS families of controllers # isp: Qlogic ISP 1020, 1040 and 1040B PCI SCSI host adapters, # ISP 1240 Dual Ultra SCSI, ISP 1080 and 1280 (Dual) Ultra2, # ISP 12160 Ultra3 SCSI, # Qlogic ISP 2100 and ISP 2200 1Gb Fibre Channel host adapters. # Qlogic ISP 2300 and ISP 2312 2Gb Fibre Channel host adapters. # Qlogic ISP 2322 and ISP 6322 2Gb Fibre Channel host adapters. # ispfw: Firmware module for Qlogic host adapters # mpt: LSI-Logic MPT/Fusion 53c1020 or 53c1030 Ultra4 # or FC9x9 Fibre Channel host adapters. # ncr: NCR 53C810, 53C825 self-contained SCSI host adapters. # sym: Symbios/Logic 53C8XX family of PCI-SCSI I/O processors: # 53C810, 53C810A, 53C815, 53C825, 53C825A, 53C860, 53C875, # 53C876, 53C885, 53C895, 53C895A, 53C896, 53C897, 53C1510D, # 53C1010-33, 53C1010-66. # trm: Tekram DC395U/UW/F DC315U adapters. # wds: WD7000 # # Note that the order is important in order for Buslogic ISA/EISA cards to be # probed correctly. # device bt hint.bt.0.at="isa" hint.bt.0.port="0x330" device adv hint.adv.0.at="isa" device adw device aha hint.aha.0.at="isa" device aic hint.aic.0.at="isa" device ahb device ahc device ahd device amd device esp device iscsi_initiator device isp hint.isp.0.disable="1" hint.isp.0.role="3" hint.isp.0.prefer_iomap="1" hint.isp.0.prefer_memmap="1" hint.isp.0.fwload_disable="1" hint.isp.0.ignore_nvram="1" hint.isp.0.fullduplex="1" hint.isp.0.topology="lport" hint.isp.0.topology="nport" hint.isp.0.topology="lport-only" hint.isp.0.topology="nport-only" # we can't get u_int64_t types, nor can we get strings if it's got # a leading 0x, hence this silly dodge. hint.isp.0.portwnn="w50000000aaaa0000" hint.isp.0.nodewnn="w50000000aaaa0001" device ispfw device mpt device ncr device sym device trm device wds hint.wds.0.at="isa" hint.wds.0.port="0x350" hint.wds.0.irq="11" hint.wds.0.drq="6" # The aic7xxx driver will attempt to use memory mapped I/O for all PCI # controllers that have it configured only if this option is set. Unfortunately, # this doesn't work on some motherboards, which prevents it from being the # default. options AHC_ALLOW_MEMIO # Dump the contents of the ahc controller configuration PROM. options AHC_DUMP_EEPROM # Bitmap of units to enable targetmode operations. options AHC_TMODE_ENABLE # Compile in Aic7xxx Debugging code. options AHC_DEBUG # Aic7xxx driver debugging options. See sys/dev/aic7xxx/aic7xxx.h options AHC_DEBUG_OPTS # Print register bitfields in debug output. Adds ~128k to driver # See ahc(4). options AHC_REG_PRETTY_PRINT # Compile in aic79xx debugging code. options AHD_DEBUG # Aic79xx driver debugging options. Adds ~215k to driver. See ahd(4). options AHD_DEBUG_OPTS=0xFFFFFFFF # Print human-readable register definitions when debugging options AHD_REG_PRETTY_PRINT # Bitmap of units to enable targetmode operations. options AHD_TMODE_ENABLE # The adw driver will attempt to use memory mapped I/O for all PCI # controllers that have it configured only if this option is set. options ADW_ALLOW_MEMIO # Options used in dev/iscsi (Software iSCSI stack) # options ISCSI_INITIATOR_DEBUG=9 # Options used in dev/isp/ (Qlogic SCSI/FC driver). # # ISP_TARGET_MODE - enable target mode operation # options ISP_TARGET_MODE=1 # # ISP_DEFAULT_ROLES - default role # none=0 # target=1 # initiator=2 # both=3 (not supported currently) # # ISP_INTERNAL_TARGET (trivial internal disk target, for testing) # -options ISP_DEFAULT_ROLES=2 +options ISP_DEFAULT_ROLES=0 # Options used in dev/sym/ (Symbios SCSI driver). #options SYM_SETUP_LP_PROBE_MAP #-Low Priority Probe Map (bits) # Allows the ncr to take precedence # 1 (1<<0) -> 810a, 860 # 2 (1<<1) -> 825a, 875, 885, 895 # 4 (1<<2) -> 895a, 896, 1510d #options SYM_SETUP_SCSI_DIFF #-HVD support for 825a, 875, 885 # disabled:0 (default), enabled:1 #options SYM_SETUP_PCI_PARITY #-PCI parity checking # disabled:0, enabled:1 (default) #options SYM_SETUP_MAX_LUN #-Number of LUNs supported # default:8, range:[1..64] # The 'dpt' driver provides support for old DPT controllers (http://www.dpt.com/). # These have hardware RAID-{0,1,5} support, and do multi-initiator I/O. # The DPT controllers are commonly re-licensed under other brand-names - # some controllers by Olivetti, Dec, HP, AT&T, SNI, AST, Alphatronic, NEC and # Compaq are actually DPT controllers. # # See src/sys/dev/dpt for debugging and other subtle options. # DPT_MEASURE_PERFORMANCE Enables a set of (semi)invasive metrics. Various # instruments are enabled. The tools in # /usr/sbin/dpt_* assume these to be enabled. # DPT_HANDLE_TIMEOUTS Normally device timeouts are handled by the DPT. # If you want the driver to handle timeouts, enable # this option. If your system is very busy, this # option will create more trouble than solve. # DPT_TIMEOUT_FACTOR Used to compute the excessive amount of time to # wait when timing out with the above option. # DPT_DEBUG_xxxx These are controllable from sys/dev/dpt/dpt.h # DPT_LOST_IRQ When enabled, will try, once per second, to catch # any interrupt that got lost. Seems to help in some # DPT-firmware/Motherboard combinations. Minimal # cost, great benefit. # DPT_RESET_HBA Make "reset" actually reset the controller # instead of fudging it. Only enable this if you # are 100% certain you need it. device dpt # DPT options #!CAM# options DPT_MEASURE_PERFORMANCE #!CAM# options DPT_HANDLE_TIMEOUTS options DPT_TIMEOUT_FACTOR=4 options DPT_LOST_IRQ options DPT_RESET_HBA # # Compaq "CISS" RAID controllers (SmartRAID 5* series) # These controllers have a SCSI-like interface, and require the # CAM infrastructure. # device ciss # # Intel Integrated RAID controllers. # This driver was developed and is maintained by Intel. Contacts # at Intel for this driver are # "Kannanthanam, Boji T" and # "Leubner, Achim" . # device iir # # Mylex AcceleRAID and eXtremeRAID controllers with v6 and later # firmware. These controllers have a SCSI-like interface, and require # the CAM infrastructure. # device mly # # Compaq Smart RAID, Mylex DAC960 and AMI MegaRAID controllers. Only # one entry is needed; the code will find and configure all supported # controllers. # device ida # Compaq Smart RAID device mlx # Mylex DAC960 device amr # AMI MegaRAID device amrp # SCSI Passthrough interface (optional, CAM req.) device mfi # LSI MegaRAID SAS device mfip # LSI MegaRAID SAS passthrough, requires CAM options MFI_DEBUG # # 3ware ATA RAID # device twe # 3ware ATA RAID # # Serial ATA host controllers: # # ahci: Advanced Host Controller Interface (AHCI) compatible # mvs: Marvell 88SX50XX/88SX60XX/88SX70XX/SoC controllers # siis: SiliconImage SiI3124/SiI3132/SiI3531 controllers # # These drivers are part of cam(4) subsystem. They supersede less featured # ata(4) subsystem drivers, supporting same hardware. device ahci device mvs device siis # # The 'ATA' driver supports all ATA and ATAPI devices, including PC Card # devices. You only need one "device ata" for it to find all # PCI and PC Card ATA/ATAPI devices on modern machines. # Alternatively, individual bus and chipset drivers may be chosen by using # the 'atacore' driver then selecting the drivers on a per vendor basis. # For example to build a system which only supports a VIA chipset, # omit 'ata' and include the 'atacore', 'atapci' and 'atavia' drivers. device ata #device atadisk # ATA disk drives #device ataraid # ATA RAID drives #device atapicd # ATAPI CDROM drives #device atapifd # ATAPI floppy drives #device atapist # ATAPI tape drives #device atapicam # emulate ATAPI devices as SCSI ditto via CAM # needs CAM to be present (scbus & pass) # Modular ATA #device atacore # Core ATA functionality #device atacard # CARDBUS support #device atabus # PC98 cbus support #device ataisa # ISA bus support #device atapci # PCI bus support; only generic chipset support # PCI ATA chipsets #device ataahci # AHCI SATA #device ataacard # ACARD #device ataacerlabs # Acer Labs Inc. (ALI) #device ataadaptec # Adaptec #device ataamd # American Micro Devices (AMD) #device ataati # ATI #device atacenatek # Cenatek #device atacypress # Cypress #device atacyrix # Cyrix #device atahighpoint # HighPoint #device ataintel # Intel #device ataite # Integrated Technology Inc. (ITE) #device atajmicron # JMicron #device atamarvell # Marvell #device atamicron # Micron #device atanational # National #device atanetcell # NetCell #device atanvidia # nVidia #device atapromise # Promise #device ataserverworks # ServerWorks #device atasiliconimage # Silicon Image Inc. (SiI) (formerly CMD) #device atasis # Silicon Integrated Systems Corp.(SiS) #device atavia # VIA Technologies Inc. # # For older non-PCI, non-PnPBIOS systems, these are the hints lines to add: hint.ata.0.at="isa" hint.ata.0.port="0x1f0" hint.ata.0.irq="14" hint.ata.1.at="isa" hint.ata.1.port="0x170" hint.ata.1.irq="15" # # The following options are valid on the ATA driver: # # ATA_STATIC_ID: controller numbering is static ie depends on location # else the device numbers are dynamically allocated. # ATA_REQUEST_TIMEOUT: the number of seconds to wait for an ATA request # before timing out. # ATA_CAM: Turn ata(4) subsystem controller drivers into cam(4) # interface modules. This deprecates all ata(4) # peripheral device drivers (atadisk, ataraid, atapicd, # atapifd, atapist, atapicam) and all user-level APIs. # cam(4) drivers and APIs will be connected instead. options ATA_STATIC_ID #options ATA_REQUEST_TIMEOUT=10 options ATA_CAM # # Standard floppy disk controllers and floppy tapes, supports # the Y-E DATA External FDD (PC Card) # device fdc hint.fdc.0.at="isa" hint.fdc.0.port="0x3F0" hint.fdc.0.irq="6" hint.fdc.0.drq="2" # # FDC_DEBUG enables floppy debugging. Since the debug output is huge, you # gotta turn it actually on by setting the variable fd_debug with DDB, # however. options FDC_DEBUG # # Activate this line if you happen to have an Insight floppy tape. # Probing them proved to be dangerous for people with floppy disks only, # so it's "hidden" behind a flag: #hint.fdc.0.flags="1" # Specify floppy devices hint.fd.0.at="fdc0" hint.fd.0.drive="0" hint.fd.1.at="fdc0" hint.fd.1.drive="1" # # uart: newbusified driver for serial interfaces. It consolidates the sio(4), # sab(4) and zs(4) drivers. # device uart # Options for uart(4) options UART_PPS_ON_CTS # Do time pulse capturing using CTS # instead of DCD. # The following hint should only be used for pure ISA devices. It is not # needed otherwise. Use of hints is strongly discouraged. hint.uart.0.at="isa" # The following 3 hints are used when the UART is a system device (i.e., a # console or debug port), but only on platforms that don't have any other # means to pass the information to the kernel. The unit number of the hint # is only used to bundle the hints together. There is no relation to the # unit number of the probed UART. hint.uart.0.port="0x3f8" hint.uart.0.flags="0x10" hint.uart.0.baud="115200" # `flags' for serial drivers that support consoles like sio(4) and uart(4): # 0x10 enable console support for this unit. Other console flags # (if applicable) are ignored unless this is set. Enabling # console support does not make the unit the preferred console. # Boot with -h or set boot_serial=YES in the loader. For sio(4) # specifically, the 0x20 flag can also be set (see above). # Currently, at most one unit can have console support; the # first one (in config file order) with this flag set is # preferred. Setting this flag for sio0 gives the old behaviour. # 0x80 use this port for serial line gdb support in ddb. Also known # as debug port. # # Options for serial drivers that support consoles: options BREAK_TO_DEBUGGER # A BREAK on a serial console goes to # ddb, if available. # Solaris implements a new BREAK which is initiated by a character # sequence CR ~ ^b which is similar to a familiar pattern used on # Sun servers by the Remote Console. There are FreeBSD extensions: # CR ~ ^p requests force panic and CR ~ ^r requests a clean reboot. options ALT_BREAK_TO_DEBUGGER # Serial Communications Controller # Supports the Siemens SAB 82532 and Zilog Z8530 multi-channel # communications controllers. device scc # PCI Universal Communications driver # Supports various multi port PCI I/O cards. device puc # # Network interfaces: # # MII bus support is required for many PCI Ethernet NICs, # namely those which use MII-compliant transceivers or implement # transceiver control interfaces that operate like an MII. Adding # "device miibus" to the kernel config pulls in support for the generic # miibus API, the common support for for bit-bang'ing the MII and all # of the PHY drivers, including a generic one for PHYs that aren't # specifically handled by an individual driver. Support for specific # PHYs may be built by adding "device mii", "device mii_bitbang" if # needed by the NIC driver and then adding the appropriate PHY driver. device mii # Minimal MII support device mii_bitbang # Common module for bit-bang'ing the MII device miibus # MII support w/ bit-bang'ing and all PHYs device acphy # Altima Communications AC101 device amphy # AMD AM79c873 / Davicom DM910{1,2} device atphy # Attansic/Atheros F1 device axphy # Asix Semiconductor AX88x9x device bmtphy # Broadcom BCM5201/BCM5202 and 3Com 3c905C device brgphy # Broadcom BCM54xx/57xx 1000baseTX device ciphy # Cicada/Vitesse CS/VSC8xxx device e1000phy # Marvell 88E1000 1000/100/10-BT device gentbi # Generic 10-bit 1000BASE-{LX,SX} fiber ifaces device icsphy # ICS ICS1889-1893 device ip1000phy # IC Plus IP1000A/IP1001 device jmphy # JMicron JMP211/JMP202 device lxtphy # Level One LXT-970 device mlphy # Micro Linear 6692 device nsgphy # NatSemi DP8361/DP83865/DP83891 device nsphy # NatSemi DP83840A device nsphyter # NatSemi DP83843/DP83815 device pnaphy # HomePNA device qsphy # Quality Semiconductor QS6612 device rdcphy # RDC Semiconductor R6040 device rgephy # RealTek 8169S/8110S/8211B/8211C device rlphy # RealTek 8139 device rlswitch # RealTek 8305 device smcphy # SMSC LAN91C111 device tdkphy # TDK 89Q2120 device tlphy # Texas Instruments ThunderLAN device truephy # LSI TruePHY device xmphy # XaQti XMAC II # an: Aironet 4500/4800 802.11 wireless adapters. Supports the PCMCIA, # PCI and ISA varieties. # ae: Support for gigabit ethernet adapters based on the Attansic/Atheros # L2 PCI-Express FastEthernet controllers. # age: Support for gigabit ethernet adapters based on the Attansic/Atheros # L1 PCI express gigabit ethernet controllers. # alc: Support for Atheros AR8131/AR8132 PCIe ethernet controllers. # ale: Support for Atheros AR8121/AR8113/AR8114 PCIe ethernet controllers. # ath: Atheros a/b/g WiFi adapters (requires ath_hal and wlan) # bce: Broadcom NetXtreme II (BCM5706/BCM5708) PCI/PCIe Gigabit Ethernet # adapters. # bfe: Broadcom BCM4401 Ethernet adapter. # bge: Support for gigabit ethernet adapters based on the Broadcom # BCM570x family of controllers, including the 3Com 3c996-T, # the Netgear GA302T, the SysKonnect SK-9D21 and SK-9D41, and # the embedded gigE NICs on Dell PowerEdge 2550 servers. # bxe: Broadcom NetXtreme II (BCM57710/57711/57711E) PCIe 10b Ethernet # adapters. # bwi: Broadcom BCM430* and BCM431* family of wireless adapters. # bwn: Broadcom BCM43xx family of wireless adapters. # cas: Sun Cassini/Cassini+ and National Semiconductor DP83065 Saturn # cm: Arcnet SMC COM90c26 / SMC COM90c56 # (and SMC COM90c66 in '56 compatibility mode) adapters. # cxgbe: Support for PCI express 10Gb/1Gb adapters based on the Chelsio T4 # (Terminator 4) ASIC. # dc: Support for PCI fast ethernet adapters based on the DEC/Intel 21143 # and various workalikes including: # the ADMtek AL981 Comet and AN985 Centaur, the ASIX Electronics # AX88140A and AX88141, the Davicom DM9100 and DM9102, the Lite-On # 82c168 and 82c169 PNIC, the Lite-On/Macronix LC82C115 PNIC II # and the Macronix 98713/98713A/98715/98715A/98725 PMAC. This driver # replaces the old al, ax, dm, pn and mx drivers. List of brands: # Digital DE500-BA, Kingston KNE100TX, D-Link DFE-570TX, SOHOware SFA110, # SVEC PN102-TX, CNet Pro110B, 120A, and 120B, Compex RL100-TX, # LinkSys LNE100TX, LNE100TX V2.0, Jaton XpressNet, Alfa Inc GFC2204, # KNE110TX. # de: Digital Equipment DC21040 # em: Intel Pro/1000 Gigabit Ethernet 82542, 82543, 82544 based adapters. # igb: Intel Pro/1000 PCI Express Gigabit Ethernet: 82575 and later adapters. # ep: 3Com 3C509, 3C529, 3C556, 3C562D, 3C563D, 3C572, 3C574X, 3C579, 3C589 # and PC Card devices using these chipsets. # ex: Intel EtherExpress Pro/10 and other i82595-based adapters, # Olicom Ethernet PC Card devices. # fe: Fujitsu MB86960A/MB86965A Ethernet # fea: DEC DEFEA EISA FDDI adapter # fpa: Support for the Digital DEFPA PCI FDDI. `device fddi' is also needed. # fxp: Intel EtherExpress Pro/100B # (hint of prefer_iomap can be done to prefer I/O instead of Mem mapping) # gem: Apple GMAC/Sun ERI/Sun GEM # hme: Sun HME (Happy Meal Ethernet) # jme: JMicron JMC260 Fast Ethernet/JMC250 Gigabit Ethernet based adapters. # le: AMD Am7900 LANCE and Am79C9xx PCnet # lge: Support for PCI gigabit ethernet adapters based on the Level 1 # LXT1001 NetCellerator chipset. This includes the D-Link DGE-500SX, # SMC TigerCard 1000 (SMC9462SX), and some Addtron cards. # malo: Marvell Libertas wireless NICs. # mwl: Marvell 88W8363 802.11n wireless NICs. # msk: Support for gigabit ethernet adapters based on the Marvell/SysKonnect # Yukon II Gigabit controllers, including 88E8021, 88E8022, 88E8061, # 88E8062, 88E8035, 88E8036, 88E8038, 88E8050, 88E8052, 88E8053, # 88E8055, 88E8056 and D-Link 560T/550SX. # lmc: Support for the LMC/SBE wide-area network interface cards. # my: Myson Fast Ethernet (MTD80X, MTD89X) # nge: Support for PCI gigabit ethernet adapters based on the National # Semiconductor DP83820 and DP83821 chipset. This includes the # SMC EZ Card 1000 (SMC9462TX), D-Link DGE-500T, Asante FriendlyNet # GigaNIX 1000TA and 1000TPC, the Addtron AEG320T, the Surecom # EP-320G-TX and the Netgear GA622T. # oce: Emulex 10 Gbit adapters (OneConnect Ethernet) # pcn: Support for PCI fast ethernet adapters based on the AMD Am79c97x # PCnet-FAST, PCnet-FAST+, PCnet-FAST III, PCnet-PRO and PCnet-Home # chipsets. These can also be handled by the le(4) driver if the # pcn(4) driver is left out of the kernel. The le(4) driver does not # support the additional features like the MII bus and burst mode of # the PCnet-FAST and greater chipsets though. # ral: Ralink Technology IEEE 802.11 wireless adapter # re: RealTek 8139C+/8169/816xS/811xS/8101E PCI/PCIe Ethernet adapter # rl: Support for PCI fast ethernet adapters based on the RealTek 8129/8139 # chipset. Note that the RealTek driver defaults to using programmed # I/O to do register accesses because memory mapped mode seems to cause # severe lockups on SMP hardware. This driver also supports the # Accton EN1207D `Cheetah' adapter, which uses a chip called # the MPX 5030/5038, which is either a RealTek in disguise or a # RealTek workalike. Note that the D-Link DFE-530TX+ uses the RealTek # chipset and is supported by this driver, not the 'vr' driver. # sf: Support for Adaptec Duralink PCI fast ethernet adapters based on the # Adaptec AIC-6915 "starfire" controller. # This includes dual and quad port cards, as well as one 100baseFX card. # Most of these are 64-bit PCI devices, except for one single port # card which is 32-bit. # sge: Silicon Integrated Systems SiS190/191 Fast/Gigabit Ethernet adapter # sis: Support for NICs based on the Silicon Integrated Systems SiS 900, # SiS 7016 and NS DP83815 PCI fast ethernet controller chips. # sk: Support for the SysKonnect SK-984x series PCI gigabit ethernet NICs. # This includes the SK-9841 and SK-9842 single port cards (single mode # and multimode fiber) and the SK-9843 and SK-9844 dual port cards # (also single mode and multimode). # The driver will autodetect the number of ports on the card and # attach each one as a separate network interface. # sn: Support for ISA and PC Card Ethernet devices using the # SMC91C90/92/94/95 chips. # ste: Sundance Technologies ST201 PCI fast ethernet controller, includes # the D-Link DFE-550TX. # stge: Support for gigabit ethernet adapters based on the Sundance/Tamarack # TC9021 family of controllers, including the Sundance ST2021/ST2023, # the Sundance/Tamarack TC9021, the D-Link DL-4000 and ASUS NX1101. # ti: Support for PCI gigabit ethernet NICs based on the Alteon Networks # Tigon 1 and Tigon 2 chipsets. This includes the Alteon AceNIC, the # 3Com 3c985, the Netgear GA620 and various others. Note that you will # probably want to bump up kern.ipc.nmbclusters a lot to use this driver. # tl: Support for the Texas Instruments TNETE100 series 'ThunderLAN' # cards and integrated ethernet controllers. This includes several # Compaq Netelligent 10/100 cards and the built-in ethernet controllers # in several Compaq Prosignia, Proliant and Deskpro systems. It also # supports several Olicom 10Mbps and 10/100 boards. # tx: SMC 9432 TX, BTX and FTX cards. (SMC EtherPower II series) # txp: Support for 3Com 3cR990 cards with the "Typhoon" chipset # vr: Support for various fast ethernet adapters based on the VIA # Technologies VT3043 `Rhine I' and VT86C100A `Rhine II' chips, # including the D-Link DFE520TX and D-Link DFE530TX (see 'rl' for # DFE530TX+), the Hawking Technologies PN102TX, and the AOpen/Acer ALN-320. # vte: DM&P Vortex86 RDC R6040 Fast Ethernet # vx: 3Com 3C590 and 3C595 # wb: Support for fast ethernet adapters based on the Winbond W89C840F chip. # Note: this is not the same as the Winbond W89C940F, which is a # NE2000 clone. # wi: Lucent WaveLAN/IEEE 802.11 PCMCIA adapters. Note: this supports both # the PCMCIA and ISA cards: the ISA card is really a PCMCIA to ISA # bridge with a PCMCIA adapter plugged into it. # xe: Xircom/Intel EtherExpress Pro100/16 PC Card ethernet controller, # Accton Fast EtherCard-16, Compaq Netelligent 10/100 PC Card, # Toshiba 10/100 Ethernet PC Card, Xircom 16-bit Ethernet + Modem 56 # xl: Support for the 3Com 3c900, 3c905, 3c905B and 3c905C (Fast) # Etherlink XL cards and integrated controllers. This includes the # integrated 3c905B-TX chips in certain Dell Optiplex and Dell # Precision desktop machines and the integrated 3c905-TX chips # in Dell Latitude laptop docking stations. # Also supported: 3Com 3c980(C)-TX, 3Com 3cSOHO100-TX, 3Com 3c450-TX # Order for ISA/EISA devices is important here device cm hint.cm.0.at="isa" hint.cm.0.port="0x2e0" hint.cm.0.irq="9" hint.cm.0.maddr="0xdc000" device ep device ex device fe hint.fe.0.at="isa" hint.fe.0.port="0x300" device fea device sn hint.sn.0.at="isa" hint.sn.0.port="0x300" hint.sn.0.irq="10" device an device wi device xe # PCI Ethernet NICs that use the common MII bus controller code. device ae # Attansic/Atheros L2 FastEthernet device age # Attansic/Atheros L1 Gigabit Ethernet device alc # Atheros AR8131/AR8132 Ethernet device ale # Atheros AR8121/AR8113/AR8114 Ethernet device bce # Broadcom BCM5706/BCM5708 Gigabit Ethernet device bfe # Broadcom BCM440x 10/100 Ethernet device bge # Broadcom BCM570xx Gigabit Ethernet device cas # Sun Cassini/Cassini+ and NS DP83065 Saturn device cxgb # Chelsio T3 10 Gigabit Ethernet device cxgb_t3fw # Chelsio T3 10 Gigabit Ethernet firmware device dc # DEC/Intel 21143 and various workalikes device et # Agere ET1310 10/100/Gigabit Ethernet device fxp # Intel EtherExpress PRO/100B (82557, 82558) hint.fxp.0.prefer_iomap="0" device gem # Apple GMAC/Sun ERI/Sun GEM device hme # Sun HME (Happy Meal Ethernet) device jme # JMicron JMC250 Gigabit/JMC260 Fast Ethernet device lge # Level 1 LXT1001 gigabit Ethernet device msk # Marvell/SysKonnect Yukon II Gigabit Ethernet device my # Myson Fast Ethernet (MTD80X, MTD89X) device nge # NatSemi DP83820 gigabit Ethernet device re # RealTek 8139C+/8169/8169S/8110S device rl # RealTek 8129/8139 device pcn # AMD Am79C97x PCI 10/100 NICs device sf # Adaptec AIC-6915 (``Starfire'') device sge # Silicon Integrated Systems SiS190/191 device sis # Silicon Integrated Systems SiS 900/SiS 7016 device sk # SysKonnect SK-984x & SK-982x gigabit Ethernet device ste # Sundance ST201 (D-Link DFE-550TX) device stge # Sundance/Tamarack TC9021 gigabit Ethernet device tl # Texas Instruments ThunderLAN device tx # SMC EtherPower II (83c170 ``EPIC'') device vr # VIA Rhine, Rhine II device vte # DM&P Vortex86 RDC R6040 Fast Ethernet device wb # Winbond W89C840F device xl # 3Com 3c90x (``Boomerang'', ``Cyclone'') # PCI Ethernet NICs. device bxe # Broadcom BCM57710/BCM57711/BCM57711E 10Gb Ethernet device cxgbe # Chelsio T4 10GbE PCIe adapter device de # DEC/Intel DC21x4x (``Tulip'') device em # Intel Pro/1000 Gigabit Ethernet device igb # Intel Pro/1000 PCIE Gigabit Ethernet device ixgb # Intel Pro/10Gbe PCI-X Ethernet device ixgbe # Intel Pro/10Gbe PCIE Ethernet device le # AMD Am7900 LANCE and Am79C9xx PCnet device mxge # Myricom Myri-10G 10GbE NIC device nxge # Neterion Xframe 10GbE Server/Storage Adapter device oce # Emulex 10 GbE (OneConnect Ethernet) device ti # Alteon Networks Tigon I/II gigabit Ethernet device txp # 3Com 3cR990 (``Typhoon'') device vx # 3Com 3c590, 3c595 (``Vortex'') device vxge # Exar/Neterion XFrame 3100 10GbE # PCI FDDI NICs. device fpa # PCI WAN adapters. device lmc # PCI IEEE 802.11 Wireless NICs device ath # Atheros pci/cardbus NIC's device ath_hal # pci/cardbus chip support #device ath_ar5210 # AR5210 chips #device ath_ar5211 # AR5211 chips #device ath_ar5212 # AR5212 chips #device ath_rf2413 #device ath_rf2417 #device ath_rf2425 #device ath_rf5111 #device ath_rf5112 #device ath_rf5413 #device ath_ar5416 # AR5416 chips options AH_SUPPORT_AR5416 # enable AR5416 tx/rx descriptors # All of the AR5212 parts have a problem when paired with the AR71xx # CPUS. These parts have a bug that triggers a fatal bus error on the AR71xx # only. Details of the exact nature of the bug are sketchy, but some can be # found at https://forum.openwrt.org/viewtopic.php?pid=70060 on pages 4, 5 and # 6. This option enables this workaround. There is a performance penalty # for this work around, but without it things don't work at all. The DMA # from the card usually bursts 128 bytes, but on the affected CPUs, only # 4 are safe. options AH_RXCFG_SDMAMW_4BYTES #device ath_ar9160 # AR9160 chips #device ath_ar9280 # AR9280 chips #device ath_ar9285 # AR9285 chips device ath_rate_sample # SampleRate tx rate control for ath device bwi # Broadcom BCM430* BCM431* device bwn # Broadcom BCM43xx device malo # Marvell Libertas wireless NICs. device mwl # Marvell 88W8363 802.11n wireless NICs. device ral # Ralink Technology RT2500 wireless NICs. # Use sf_buf(9) interface for jumbo buffers on ti(4) controllers. #options TI_SF_BUF_JUMBO # Turn on the header splitting option for the ti(4) driver firmware. This # only works for Tigon II chips, and has no effect for Tigon I chips. # This option requires the TI_SF_BUF_JUMBO option above. #options TI_JUMBO_HDRSPLIT # # Use header splitting feature on bce(4) adapters. # This may help to reduce the amount of jumbo-sized memory buffers used. # options BCE_JUMBO_HDRSPLIT # These two options allow manipulating the mbuf cluster size and mbuf size, # respectively. Be very careful with NIC driver modules when changing # these from their default values, because that can potentially cause a # mismatch between the mbuf size assumed by the kernel and the mbuf size # assumed by a module. The only driver that currently has the ability to # detect a mismatch is ti(4). options MCLSHIFT=12 # mbuf cluster shift in bits, 12 == 4KB options MSIZE=512 # mbuf size in bytes # # ATM related options (Cranor version) # (note: this driver cannot be used with the HARP ATM stack) # # The `en' device provides support for Efficient Networks (ENI) # ENI-155 PCI midway cards, and the Adaptec 155Mbps PCI ATM cards (ANA-59x0). # # The `hatm' device provides support for Fore/Marconi HE155 and HE622 # ATM PCI cards. # # The `fatm' device provides support for Fore PCA200E ATM PCI cards. # # The `patm' device provides support for IDT77252 based cards like # ProSum's ProATM-155 and ProATM-25 and IDT's evaluation boards. # # atm device provides generic atm functions and is required for # atm devices. # NATM enables the netnatm protocol family that can be used to # bypass TCP/IP. # # utopia provides the access to the ATM PHY chips and is required for en, # hatm and fatm. # # the current driver supports only PVC operations (no atm-arp, no multicast). # for more details, please read the original documents at # http://www.ccrc.wustl.edu/pub/chuck/tech/bsdatm/bsdatm.html # device atm device en device fatm #Fore PCA200E device hatm #Fore/Marconi HE155/622 device patm #IDT77252 cards (ProATM and IDT) device utopia #ATM PHY driver options NATM #native ATM options LIBMBPOOL #needed by patm, iatm # # Sound drivers # # sound: The generic sound driver. # device sound # # snd_*: Device-specific drivers. # # The flags of the device tell the device a bit more info about the # device that normally is obtained through the PnP interface. # bit 2..0 secondary DMA channel; # bit 4 set if the board uses two dma channels; # bit 15..8 board type, overrides autodetection; leave it # zero if don't know what to put in (and you don't, # since this is unsupported at the moment...). # # snd_ad1816: Analog Devices AD1816 ISA PnP/non-PnP. # snd_als4000: Avance Logic ALS4000 PCI. # snd_atiixp: ATI IXP 200/300/400 PCI. # snd_audiocs: Crystal Semiconductor CS4231 SBus/EBus. Only # for sparc64. # snd_cmi: CMedia CMI8338/CMI8738 PCI. # snd_cs4281: Crystal Semiconductor CS4281 PCI. # snd_csa: Crystal Semiconductor CS461x/428x PCI. (except # 4281) # snd_ds1: Yamaha DS-1 PCI. # snd_emu10k1: Creative EMU10K1 PCI and EMU10K2 (Audigy) PCI. # snd_emu10kx: Creative SoundBlaster Live! and Audigy # snd_envy24: VIA Envy24 and compatible, needs snd_spicds. # snd_envy24ht: VIA Envy24HT and compatible, needs snd_spicds. # snd_es137x: Ensoniq AudioPCI ES137x PCI. # snd_ess: Ensoniq ESS ISA PnP/non-PnP, to be used in # conjunction with snd_sbc. # snd_fm801: Forte Media FM801 PCI. # snd_gusc: Gravis UltraSound ISA PnP/non-PnP. # snd_hda: Intel High Definition Audio (Controller) and # compatible. # snd_hdspe: RME HDSPe AIO and RayDAT. # snd_ich: Intel ICH AC'97 and some more audio controllers # embedded in a chipset, for example nVidia # nForce controllers. # snd_maestro: ESS Technology Maestro-1/2x PCI. # snd_maestro3: ESS Technology Maestro-3/Allegro PCI. # snd_mss: Microsoft Sound System ISA PnP/non-PnP. # snd_neomagic: Neomagic 256 AV/ZX PCI. # snd_sb16: Creative SoundBlaster16, to be used in # conjunction with snd_sbc. # snd_sb8: Creative SoundBlaster (pre-16), to be used in # conjunction with snd_sbc. # snd_sbc: Creative SoundBlaster ISA PnP/non-PnP. # Supports ESS and Avance ISA chips as well. # snd_solo: ESS Solo-1x PCI. # snd_spicds: SPI codec driver, needed by Envy24/Envy24HT drivers. # snd_t4dwave: Trident 4DWave DX/NX PCI, Sis 7018 PCI and Acer Labs # M5451 PCI. # snd_uaudio: USB audio. # snd_via8233: VIA VT8233x PCI. # snd_via82c686: VIA VT82C686A PCI. # snd_vibes: S3 Sonicvibes PCI. device snd_ad1816 device snd_als4000 device snd_atiixp #device snd_audiocs device snd_cmi device snd_cs4281 device snd_csa device snd_ds1 device snd_emu10k1 device snd_emu10kx device snd_envy24 device snd_envy24ht device snd_es137x device snd_ess device snd_fm801 device snd_gusc device snd_hda device snd_hdspe device snd_ich device snd_maestro device snd_maestro3 device snd_mss device snd_neomagic device snd_sb16 device snd_sb8 device snd_sbc device snd_solo device snd_spicds device snd_t4dwave device snd_uaudio device snd_via8233 device snd_via82c686 device snd_vibes # For non-PnP sound cards: hint.pcm.0.at="isa" hint.pcm.0.irq="10" hint.pcm.0.drq="1" hint.pcm.0.flags="0x0" hint.sbc.0.at="isa" hint.sbc.0.port="0x220" hint.sbc.0.irq="5" hint.sbc.0.drq="1" hint.sbc.0.flags="0x15" hint.gusc.0.at="isa" hint.gusc.0.port="0x220" hint.gusc.0.irq="5" hint.gusc.0.drq="1" hint.gusc.0.flags="0x13" # # Following options are intended for debugging/testing purposes: # # SND_DEBUG Enable extra debugging code that includes # sanity checking and possible increase of # verbosity. # # SND_DIAGNOSTIC Simmilar in a spirit of INVARIANTS/DIAGNOSTIC, # zero tolerance against inconsistencies. # # SND_FEEDER_MULTIFORMAT By default, only 16/32 bit feeders are compiled # in. This options enable most feeder converters # except for 8bit. WARNING: May bloat the kernel. # # SND_FEEDER_FULL_MULTIFORMAT Ditto, but includes 8bit feeders as well. # # SND_FEEDER_RATE_HP (feeder_rate) High precision 64bit arithmetic # as much as possible (the default trying to # avoid it). Possible slowdown. # # SND_PCM_64 (Only applicable for i386/32bit arch) # Process 32bit samples through 64bit # integer/arithmetic. Slight increase of dynamic # range at a cost of possible slowdown. # # SND_OLDSTEREO Only 2 channels are allowed, effectively # disabling multichannel processing. # options SND_DEBUG options SND_DIAGNOSTIC options SND_FEEDER_MULTIFORMAT options SND_FEEDER_FULL_MULTIFORMAT options SND_FEEDER_RATE_HP options SND_PCM_64 options SND_OLDSTEREO # # IEEE-488 hardware: # pcii: PCIIA cards (uPD7210 based isa cards) # tnt4882: National Instruments PCI-GPIB card. device pcii hint.pcii.0.at="isa" hint.pcii.0.port="0x2e1" hint.pcii.0.irq="5" hint.pcii.0.drq="1" device tnt4882 # # Miscellaneous hardware: # # scd: Sony CD-ROM using proprietary (non-ATAPI) interface # mcd: Mitsumi CD-ROM using proprietary (non-ATAPI) interface # bktr: Brooktree bt848/848a/849a/878/879 video capture and TV Tuner board # joy: joystick (including IO DATA PCJOY PC Card joystick) # cmx: OmniKey CardMan 4040 pccard smartcard reader # Mitsumi CD-ROM device mcd hint.mcd.0.at="isa" hint.mcd.0.port="0x300" # for the Sony CDU31/33A CDROM device scd hint.scd.0.at="isa" hint.scd.0.port="0x230" device joy # PnP aware, hints for non-PnP only hint.joy.0.at="isa" hint.joy.0.port="0x201" device cmx # # The 'bktr' device is a PCI video capture device using the Brooktree # bt848/bt848a/bt849a/bt878/bt879 chipset. When used with a TV Tuner it forms a # TV card, e.g. Miro PC/TV, Hauppauge WinCast/TV WinTV, VideoLogic Captivator, # Intel Smart Video III, AverMedia, IMS Turbo, FlyVideo. # # options OVERRIDE_CARD=xxx # options OVERRIDE_TUNER=xxx # options OVERRIDE_MSP=1 # options OVERRIDE_DBX=1 # These options can be used to override the auto detection # The current values for xxx are found in src/sys/dev/bktr/bktr_card.h # Using sysctl(8) run-time overrides on a per-card basis can be made # # options BROOKTREE_SYSTEM_DEFAULT=BROOKTREE_PAL # or # options BROOKTREE_SYSTEM_DEFAULT=BROOKTREE_NTSC # Specifies the default video capture mode. # This is required for Dual Crystal (28&35MHz) boards where PAL is used # to prevent hangs during initialisation, e.g. VideoLogic Captivator PCI. # # options BKTR_USE_PLL # This is required for PAL or SECAM boards with a 28MHz crystal and no 35MHz # crystal, e.g. some new Bt878 cards. # # options BKTR_GPIO_ACCESS # This enables IOCTLs which give user level access to the GPIO port. # # options BKTR_NO_MSP_RESET # Prevents the MSP34xx reset. Good if you initialise the MSP in another OS first # # options BKTR_430_FX_MODE # Switch Bt878/879 cards into Intel 430FX chipset compatibility mode. # # options BKTR_SIS_VIA_MODE # Switch Bt878/879 cards into SIS/VIA chipset compatibility mode which is # needed for some old SiS and VIA chipset motherboards. # This also allows Bt878/879 chips to work on old OPTi (<1997) chipset # motherboards and motherboards with bad or incomplete PCI 2.1 support. # As a rough guess, old = before 1998 # # options BKTR_NEW_MSP34XX_DRIVER # Use new, more complete initialization scheme for the msp34* soundchip. # Should fix stereo autodetection if the old driver does only output # mono sound. # # options BKTR_USE_FREEBSD_SMBUS # Compile with FreeBSD SMBus implementation # # Brooktree driver has been ported to the new I2C framework. Thus, # you'll need to have the following 3 lines in the kernel config. # device smbus # device iicbus # device iicbb # device iicsmb # The iic and smb devices are only needed if you want to control other # I2C slaves connected to the external connector of some cards. # device bktr # # PC Card/PCMCIA and Cardbus # # cbb: pci/cardbus bridge implementing YENTA interface # pccard: pccard slots # cardbus: cardbus slots device cbb device pccard device cardbus # # MMC/SD # # mmc MMC/SD bus # mmcsd MMC/SD memory card # sdhci Generic PCI SD Host Controller # device mmc device mmcsd device sdhci # # SMB bus # # System Management Bus support is provided by the 'smbus' device. # Access to the SMBus device is via the 'smb' device (/dev/smb*), # which is a child of the 'smbus' device. # # Supported devices: # smb standard I/O through /dev/smb* # # Supported SMB interfaces: # iicsmb I2C to SMB bridge with any iicbus interface # bktr brooktree848 I2C hardware interface # intpm Intel PIIX4 (82371AB, 82443MX) Power Management Unit # alpm Acer Aladdin-IV/V/Pro2 Power Management Unit # ichsmb Intel ICH SMBus controller chips (82801AA, 82801AB, 82801BA) # viapm VIA VT82C586B/596B/686A and VT8233 Power Management Unit # amdpm AMD 756 Power Management Unit # amdsmb AMD 8111 SMBus 2.0 Controller # nfpm NVIDIA nForce Power Management Unit # nfsmb NVIDIA nForce2/3/4 MCP SMBus 2.0 Controller # device smbus # Bus support, required for smb below. device intpm device alpm device ichsmb device viapm device amdpm device amdsmb device nfpm device nfsmb device smb # # I2C Bus # # Philips i2c bus support is provided by the `iicbus' device. # # Supported devices: # ic i2c network interface # iic i2c standard io # iicsmb i2c to smb bridge. Allow i2c i/o with smb commands. # # Supported interfaces: # bktr brooktree848 I2C software interface # # Other: # iicbb generic I2C bit-banging code (needed by lpbb, bktr) # device iicbus # Bus support, required for ic/iic/iicsmb below. device iicbb device ic device iic device iicsmb # smb over i2c bridge # I2C peripheral devices # # ds133x Dallas Semiconductor DS1337, DS1338 and DS1339 RTC # ds1672 Dallas Semiconductor DS1672 RTC # device ds133x device ds1672 # Parallel-Port Bus # # Parallel port bus support is provided by the `ppbus' device. # Multiple devices may be attached to the parallel port, devices # are automatically probed and attached when found. # # Supported devices: # vpo Iomega Zip Drive # Requires SCSI disk support ('scbus' and 'da'), best # performance is achieved with ports in EPP 1.9 mode. # lpt Parallel Printer # plip Parallel network interface # ppi General-purpose I/O ("Geek Port") + IEEE1284 I/O # pps Pulse per second Timing Interface # lpbb Philips official parallel port I2C bit-banging interface # pcfclock Parallel port clock driver. # # Supported interfaces: # ppc ISA-bus parallel port interfaces. # options PPC_PROBE_CHIPSET # Enable chipset specific detection # (see flags in ppc(4)) options DEBUG_1284 # IEEE1284 signaling protocol debug options PERIPH_1284 # Makes your computer act as an IEEE1284 # compliant peripheral options DONTPROBE_1284 # Avoid boot detection of PnP parallel devices options VP0_DEBUG # ZIP/ZIP+ debug options LPT_DEBUG # Printer driver debug options PPC_DEBUG # Parallel chipset level debug options PLIP_DEBUG # Parallel network IP interface debug options PCFCLOCK_VERBOSE # Verbose pcfclock driver options PCFCLOCK_MAX_RETRIES=5 # Maximum read tries (default 10) device ppc hint.ppc.0.at="isa" hint.ppc.0.irq="7" device ppbus device vpo device lpt device plip device ppi device pps device lpbb device pcfclock # Kernel BOOTP support options BOOTP # Use BOOTP to obtain IP address/hostname # Requires NFSCLIENT and NFS_ROOT options BOOTP_NFSROOT # NFS mount root filesystem using BOOTP info options BOOTP_NFSV3 # Use NFS v3 to NFS mount root options BOOTP_COMPAT # Workaround for broken bootp daemons. options BOOTP_WIRED_TO=fxp0 # Use interface fxp0 for BOOTP options BOOTP_BLOCKSIZE=8192 # Override NFS block size # # Add software watchdog routines. # options SW_WATCHDOG # # Add the software deadlock resolver thread. # options DEADLKRES # # Disable swapping of stack pages. This option removes all # code which actually performs swapping, so it's not possible to turn # it back on at run-time. # # This is sometimes usable for systems which don't have any swap space # (see also sysctls "vm.defer_swapspace_pageouts" and # "vm.disable_swapspace_pageouts") # #options NO_SWAPPING # Set the number of sf_bufs to allocate. sf_bufs are virtual buffers # for sendfile(2) that are used to map file VM pages, and normally # default to a quantity that is roughly 16*MAXUSERS+512. You would # typically want about 4 of these for each simultaneous file send. # options NSFBUFS=1024 # # Enable extra debugging code for locks. This stores the filename and # line of whatever acquired the lock in the lock itself, and changes a # number of function calls to pass around the relevant data. This is # not at all useful unless you are debugging lock code. Also note # that it is likely to break e.g. fstat(1) unless you recompile your # userland with -DDEBUG_LOCKS as well. # options DEBUG_LOCKS ##################################################################### # USB support # UHCI controller device uhci # OHCI controller device ohci # EHCI controller device ehci # XHCI controller device xhci # SL811 Controller #device slhci # General USB code (mandatory for USB) device usb # # USB Double Bulk Pipe devices device udbp # USB Fm Radio device ufm # Human Interface Device (anything with buttons and dials) device uhid # USB keyboard device ukbd # USB printer device ulpt # USB mass storage driver (Requires scbus and da) device umass # USB mass storage driver for device-side mode device usfs # USB support for Belkin F5U109 and Magic Control Technology serial adapters device umct # USB modem support device umodem # USB mouse device ums # eGalax USB touch screen device uep # Diamond Rio 500 MP3 player device urio # # USB serial support device ucom # USB support for 3G modem cards by Option, Novatel, Huawei and Sierra device u3g # USB support for Technologies ARK3116 based serial adapters device uark # USB support for Belkin F5U103 and compatible serial adapters device ubsa # USB support for serial adapters based on the FT8U100AX and FT8U232AM device uftdi # USB support for some Windows CE based serial communication. device uipaq # USB support for Prolific PL-2303 serial adapters device uplcom # USB support for Silicon Laboratories CP2101/CP2102 based USB serial adapters device uslcom # USB Visor and Palm devices device uvisor # USB serial support for DDI pocket's PHS device uvscom # # ADMtek USB ethernet. Supports the LinkSys USB100TX, # the Billionton USB100, the Melco LU-ATX, the D-Link DSB-650TX # and the SMC 2202USB. Also works with the ADMtek AN986 Pegasus # eval board. device aue # ASIX Electronics AX88172 USB 2.0 ethernet driver. Used in the # LinkSys USB200M and various other adapters. device axe # # Devices which communicate using Ethernet over USB, particularly # Communication Device Class (CDC) Ethernet specification. Supports # Sharp Zaurus PDAs, some DOCSIS cable modems and so on. device cdce # # CATC USB-EL1201A USB ethernet. Supports the CATC Netmate # and Netmate II, and the Belkin F5U111. device cue # # Kawasaki LSI ethernet. Supports the LinkSys USB10T, # Entrega USB-NET-E45, Peracom Ethernet Adapter, the # 3Com 3c19250, the ADS Technologies USB-10BT, the ATen UC10T, # the Netgear EA101, the D-Link DSB-650, the SMC 2102USB # and 2104USB, and the Corega USB-T. device kue # # RealTek RTL8150 USB to fast ethernet. Supports the Melco LUA-KTX # and the GREEN HOUSE GH-USB100B. device rue # # Davicom DM9601E USB to fast ethernet. Supports the Corega FEther USB-TXC. device udav # # Moschip MCS7730/MCS7840 USB to fast ethernet. Supports the Sitecom LN030. device mos # # HSxPA devices from Option N.V device uhso # # Ralink Technology RT2501USB/RT2601USB wireless driver device rum # Ralink Technology RT2700U/RT2800U/RT3000U wireless driver device run # # Atheros AR5523 wireless driver device uath # # Conexant/Intersil PrismGT wireless driver device upgt # # Ralink Technology RT2500USB wireless driver device ural # # Realtek RTL8187B/L wireless driver device urtw # # ZyDas ZD1211/ZD1211B wireless driver device zyd # # debugging options for the USB subsystem # options USB_DEBUG options U3G_DEBUG # options for ukbd: options UKBD_DFLT_KEYMAP # specify the built-in keymap makeoptions UKBD_DFLT_KEYMAP=it.iso # options for uplcom: options UPLCOM_INTR_INTERVAL=100 # interrupt pipe interval # in milliseconds # options for uvscom: options UVSCOM_DEFAULT_OPKTSIZE=8 # default output packet size options UVSCOM_INTR_INTERVAL=100 # interrupt pipe interval # in milliseconds ##################################################################### # FireWire support device firewire # FireWire bus code device sbp # SCSI over Firewire (Requires scbus and da) device sbp_targ # SBP-2 Target mode (Requires scbus and targ) device fwe # Ethernet over FireWire (non-standard!) device fwip # IP over FireWire (RFC2734 and RFC3146) ##################################################################### # dcons support (Dumb Console Device) device dcons # dumb console driver device dcons_crom # FireWire attachment options DCONS_BUF_SIZE=16384 # buffer size options DCONS_POLL_HZ=100 # polling rate options DCONS_FORCE_CONSOLE=0 # force to be the primary console options DCONS_FORCE_GDB=1 # force to be the gdb device ##################################################################### # crypto subsystem # # This is a port of the OpenBSD crypto framework. Include this when # configuring IPSEC and when you have a h/w crypto device to accelerate # user applications that link to OpenSSL. # # Drivers are ports from OpenBSD with some simple enhancements that have # been fed back to OpenBSD. device crypto # core crypto support device cryptodev # /dev/crypto for access to h/w device rndtest # FIPS 140-2 entropy tester device hifn # Hifn 7951, 7781, etc. options HIFN_DEBUG # enable debugging support: hw.hifn.debug options HIFN_RNDTEST # enable rndtest support device ubsec # Broadcom 5501, 5601, 58xx options UBSEC_DEBUG # enable debugging support: hw.ubsec.debug options UBSEC_RNDTEST # enable rndtest support ##################################################################### # # Embedded system options: # # An embedded system might want to run something other than init. options INIT_PATH=/sbin/init:/stand/sysinstall # Debug options options BUS_DEBUG # enable newbus debugging options DEBUG_VFS_LOCKS # enable VFS lock debugging options SOCKBUF_DEBUG # enable sockbuf last record/mb tail checking # # Verbose SYSINIT # # Make the SYSINIT process performed by mi_startup() verbose. This is very # useful when porting to a new architecture. If DDB is also enabled, this # will print function names instead of addresses. options VERBOSE_SYSINIT ##################################################################### # SYSV IPC KERNEL PARAMETERS # # Maximum number of System V semaphores that can be used on the system at # one time. options SEMMNI=11 # Total number of semaphores system wide options SEMMNS=61 # Total number of undo structures in system options SEMMNU=31 # Maximum number of System V semaphores that can be used by a single process # at one time. options SEMMSL=61 # Maximum number of operations that can be outstanding on a single System V # semaphore at one time. options SEMOPM=101 # Maximum number of undo operations that can be outstanding on a single # System V semaphore at one time. options SEMUME=11 # Maximum number of shared memory pages system wide. options SHMALL=1025 # Maximum size, in bytes, of a single System V shared memory region. options SHMMAX=(SHMMAXPGS*PAGE_SIZE+1) options SHMMAXPGS=1025 # Minimum size, in bytes, of a single System V shared memory region. options SHMMIN=2 # Maximum number of shared memory regions that can be used on the system # at one time. options SHMMNI=33 # Maximum number of System V shared memory regions that can be attached to # a single process at one time. options SHMSEG=9 # Compress user core dumps. options COMPRESS_USER_CORES # required to compress file output from kernel for COMPRESS_USER_CORES. device gzio # Set the amount of time (in seconds) the system will wait before # rebooting automatically when a kernel panic occurs. If set to (-1), # the system will wait indefinitely until a key is pressed on the # console. options PANIC_REBOOT_WAIT_TIME=16 # Attempt to bypass the buffer cache and put data directly into the # userland buffer for read operation when O_DIRECT flag is set on the # file. Both offset and length of the read operation must be # multiples of the physical media sector size. # options DIRECTIO # Specify a lower limit for the number of swap I/O buffers. They are # (among other things) used when bypassing the buffer cache due to # DIRECTIO kernel option enabled and O_DIRECT flag set on file. # options NSWBUF_MIN=120 ##################################################################### # More undocumented options for linting. # Note that documenting these is not considered an affront. options CAM_DEBUG_DELAY # VFS cluster debugging. options CLUSTERDEBUG options DEBUG # Kernel filelock debugging. options LOCKF_DEBUG # System V compatible message queues # Please note that the values provided here are used to test kernel # building. The defaults in the sources provide almost the same numbers. # MSGSSZ must be a power of 2 between 8 and 1024. options MSGMNB=2049 # Max number of chars in queue options MSGMNI=41 # Max number of message queue identifiers options MSGSEG=2049 # Max number of message segments options MSGSSZ=16 # Size of a message segment options MSGTQL=41 # Max number of messages in system options NBUF=512 # Number of buffer headers options SCSI_NCR_DEBUG options SCSI_NCR_MAX_SYNC=10000 options SCSI_NCR_MAX_WIDE=1 options SCSI_NCR_MYADDR=7 options SC_DEBUG_LEVEL=5 # Syscons debug level options SC_RENDER_DEBUG # syscons rendering debugging options VFS_BIO_DEBUG # VFS buffer I/O debugging options KSTACK_MAX_PAGES=32 # Maximum pages to give the kernel stack # Adaptec Array Controller driver options options AAC_DEBUG # Debugging levels: # 0 - quiet, only emit warnings # 1 - noisy, emit major function # points and things done # 2 - extremely noisy, emit trace # items in loops, etc. # Resource Accounting options RACCT # Resource Limits options RCTL # Yet more undocumented options for linting. # BKTR_ALLOC_PAGES has no effect except to cause warnings, and # BROOKTREE_ALLOC_PAGES hasn't actually been superseded by it, since the # driver still mostly spells this option BROOKTREE_ALLOC_PAGES. ##options BKTR_ALLOC_PAGES=(217*4+1) options BROOKTREE_ALLOC_PAGES=(217*4+1) options MAXFILES=999 Index: stable/9/sys/conf =================================================================== --- stable/9/sys/conf (revision 237207) +++ stable/9/sys/conf (revision 237208) Property changes on: stable/9/sys/conf ___________________________________________________________________ Modified: svn:mergeinfo ## -0,0 +0,1 ## Merged /head/sys/conf:r236427 Index: stable/9/sys/dev/isp/isp.c =================================================================== --- stable/9/sys/dev/isp/isp.c (revision 237207) +++ stable/9/sys/dev/isp/isp.c (revision 237208) @@ -1,8303 +1,8308 @@ /*- * Copyright (c) 1997-2009 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. * */ /* * Machine and OS Independent (well, as best as possible) * code for the Qlogic ISP SCSI and FC-SCSI adapters. */ /* * Inspiration and ideas about this driver are from Erik Moe's Linux driver * (qlogicisp.c) and Dave Miller's SBus version of same (qlogicisp.c). Some * ideas dredged from the Solaris driver. */ /* * Include header file appropriate for platform we're building on. */ #ifdef __NetBSD__ #include __KERNEL_RCSID(0, "$NetBSD$"); #include #endif #ifdef __FreeBSD__ #include __FBSDID("$FreeBSD$"); #include #endif #ifdef __OpenBSD__ #include #endif #ifdef __linux__ #include "isp_linux.h" #endif #ifdef __svr4__ #include "isp_solaris.h" #endif /* * General defines */ #define MBOX_DELAY_COUNT 1000000 / 100 #define ISP_MARK_PORTDB(a, b, c) \ isp_prt(isp, ISP_LOGSANCFG, \ "Chan %d ISP_MARK_PORTDB@LINE %d", b, __LINE__); \ isp_mark_portdb(a, b, c) /* * Local static data */ static const char fconf[] = "Chan %d PortDB[%d] changed:\n current =(0x%x@0x%06x 0x%08x%08x 0x%08x%08x)\n database=(0x%x@0x%06x 0x%08x%08x 0x%08x%08x)"; static const char notresp[] = "Not RESPONSE in RESPONSE Queue (type 0x%x) @ idx %d (next %d) nlooked %d"; static const char topology[] = "Chan %d WWPN 0x%08x%08x PortID 0x%06x N-Port Handle %d, Connection '%s'"; static const char sc4[] = "NVRAM"; static const char bun[] = "bad underrun (count %d, resid %d, status %s)"; static const char lipd[] = "Chan %d LIP destroyed %d active commands"; static const char sacq[] = "unable to acquire scratch area"; static const uint8_t alpa_map[] = { 0xef, 0xe8, 0xe4, 0xe2, 0xe1, 0xe0, 0xdc, 0xda, 0xd9, 0xd6, 0xd5, 0xd4, 0xd3, 0xd2, 0xd1, 0xce, 0xcd, 0xcc, 0xcb, 0xca, 0xc9, 0xc7, 0xc6, 0xc5, 0xc3, 0xbc, 0xba, 0xb9, 0xb6, 0xb5, 0xb4, 0xb3, 0xb2, 0xb1, 0xae, 0xad, 0xac, 0xab, 0xaa, 0xa9, 0xa7, 0xa6, 0xa5, 0xa3, 0x9f, 0x9e, 0x9d, 0x9b, 0x98, 0x97, 0x90, 0x8f, 0x88, 0x84, 0x82, 0x81, 0x80, 0x7c, 0x7a, 0x79, 0x76, 0x75, 0x74, 0x73, 0x72, 0x71, 0x6e, 0x6d, 0x6c, 0x6b, 0x6a, 0x69, 0x67, 0x66, 0x65, 0x63, 0x5c, 0x5a, 0x59, 0x56, 0x55, 0x54, 0x53, 0x52, 0x51, 0x4e, 0x4d, 0x4c, 0x4b, 0x4a, 0x49, 0x47, 0x46, 0x45, 0x43, 0x3c, 0x3a, 0x39, 0x36, 0x35, 0x34, 0x33, 0x32, 0x31, 0x2e, 0x2d, 0x2c, 0x2b, 0x2a, 0x29, 0x27, 0x26, 0x25, 0x23, 0x1f, 0x1e, 0x1d, 0x1b, 0x18, 0x17, 0x10, 0x0f, 0x08, 0x04, 0x02, 0x01, 0x00 }; /* * Local function prototypes. */ static int isp_parse_async(ispsoftc_t *, uint16_t); static int isp_parse_async_fc(ispsoftc_t *, uint16_t); static int isp_handle_other_response(ispsoftc_t *, int, isphdr_t *, uint32_t *); static void isp_parse_status(ispsoftc_t *, ispstatusreq_t *, XS_T *, long *); static void isp_parse_status_24xx(ispsoftc_t *, isp24xx_statusreq_t *, XS_T *, long *); static void isp_fastpost_complete(ispsoftc_t *, uint32_t); static int isp_mbox_continue(ispsoftc_t *); static void isp_scsi_init(ispsoftc_t *); static void isp_scsi_channel_init(ispsoftc_t *, int); static void isp_fibre_init(ispsoftc_t *); static void isp_fibre_init_2400(ispsoftc_t *); static void isp_mark_portdb(ispsoftc_t *, int, int); static int isp_plogx(ispsoftc_t *, int, uint16_t, uint32_t, int, int); static int isp_port_login(ispsoftc_t *, uint16_t, uint32_t); static int isp_port_logout(ispsoftc_t *, uint16_t, uint32_t); static int isp_getpdb(ispsoftc_t *, int, uint16_t, isp_pdb_t *, int); static void isp_dump_chip_portdb(ispsoftc_t *, int, int); static uint64_t isp_get_wwn(ispsoftc_t *, int, int, int); static int isp_fclink_test(ispsoftc_t *, int, int); static int isp_pdb_sync(ispsoftc_t *, int); static int isp_scan_loop(ispsoftc_t *, int); static int isp_gid_ft_sns(ispsoftc_t *, int); static int isp_gid_ft_ct_passthru(ispsoftc_t *, int); static int isp_scan_fabric(ispsoftc_t *, int); static int isp_login_device(ispsoftc_t *, int, uint32_t, isp_pdb_t *, uint16_t *); static int isp_register_fc4_type(ispsoftc_t *, int); static int isp_register_fc4_type_24xx(ispsoftc_t *, int); static uint16_t isp_nxt_handle(ispsoftc_t *, int, uint16_t); static void isp_fw_state(ispsoftc_t *, int); static void isp_mboxcmd_qnw(ispsoftc_t *, mbreg_t *, int); static void isp_mboxcmd(ispsoftc_t *, mbreg_t *); static void isp_spi_update(ispsoftc_t *, int); static void isp_setdfltsdparm(ispsoftc_t *); static void isp_setdfltfcparm(ispsoftc_t *, int); static int isp_read_nvram(ispsoftc_t *, int); static int isp_read_nvram_2400(ispsoftc_t *, uint8_t *); static void isp_rdnvram_word(ispsoftc_t *, int, uint16_t *); static void isp_rd_2400_nvram(ispsoftc_t *, uint32_t, uint32_t *); static void isp_parse_nvram_1020(ispsoftc_t *, uint8_t *); static void isp_parse_nvram_1080(ispsoftc_t *, int, uint8_t *); static void isp_parse_nvram_12160(ispsoftc_t *, int, uint8_t *); static void isp_parse_nvram_2100(ispsoftc_t *, uint8_t *); static void isp_parse_nvram_2400(ispsoftc_t *, uint8_t *); /* * Reset Hardware. * * Hit the chip over the head, download new f/w if available and set it running. * * Locking done elsewhere. */ void isp_reset(ispsoftc_t *isp, int do_load_defaults) { mbreg_t mbs; uint32_t code_org, val; int loops, i, dodnld = 1; const char *btype = "????"; static const char dcrc[] = "Downloaded RISC Code Checksum Failure"; isp->isp_state = ISP_NILSTATE; if (isp->isp_dead) { isp_shutdown(isp); ISP_DISABLE_INTS(isp); return; } /* * Basic types (SCSI, FibreChannel and PCI or SBus) * have been set in the MD code. We figure out more * here. Possibly more refined types based upon PCI * identification. Chip revision has been gathered. * * After we've fired this chip up, zero out the conf1 register * for SCSI adapters and do other settings for the 2100. */ ISP_DISABLE_INTS(isp); /* * Pick an initial maxcmds value which will be used * to allocate xflist pointer space. It may be changed * later by the firmware. */ if (IS_24XX(isp)) { isp->isp_maxcmds = 4096; } else if (IS_2322(isp)) { isp->isp_maxcmds = 2048; } else if (IS_23XX(isp) || IS_2200(isp)) { isp->isp_maxcmds = 1024; } else { isp->isp_maxcmds = 512; } /* * Set up DMA for the request and response queues. * * We do this now so we can use the request queue * for dma to load firmware from. */ if (ISP_MBOXDMASETUP(isp) != 0) { isp_prt(isp, ISP_LOGERR, "Cannot setup DMA"); return; } /* * Set up default request/response queue in-pointer/out-pointer * register indices. */ if (IS_24XX(isp)) { isp->isp_rqstinrp = BIU2400_REQINP; isp->isp_rqstoutrp = BIU2400_REQOUTP; isp->isp_respinrp = BIU2400_RSPINP; isp->isp_respoutrp = BIU2400_RSPOUTP; } else if (IS_23XX(isp)) { isp->isp_rqstinrp = BIU_REQINP; isp->isp_rqstoutrp = BIU_REQOUTP; isp->isp_respinrp = BIU_RSPINP; isp->isp_respoutrp = BIU_RSPOUTP; } else { isp->isp_rqstinrp = INMAILBOX4; isp->isp_rqstoutrp = OUTMAILBOX4; isp->isp_respinrp = OUTMAILBOX5; isp->isp_respoutrp = INMAILBOX5; } /* * Put the board into PAUSE mode (so we can read the SXP registers * or write FPM/FBM registers). */ if (IS_24XX(isp)) { ISP_WRITE(isp, BIU2400_HCCR, HCCR_2400_CMD_CLEAR_HOST_INT); ISP_WRITE(isp, BIU2400_HCCR, HCCR_2400_CMD_CLEAR_RISC_INT); ISP_WRITE(isp, BIU2400_HCCR, HCCR_2400_CMD_PAUSE); } else { ISP_WRITE(isp, HCCR, HCCR_CMD_PAUSE); } if (IS_FC(isp)) { switch (isp->isp_type) { case ISP_HA_FC_2100: btype = "2100"; break; case ISP_HA_FC_2200: btype = "2200"; break; case ISP_HA_FC_2300: btype = "2300"; break; case ISP_HA_FC_2312: btype = "2312"; break; case ISP_HA_FC_2322: btype = "2322"; break; case ISP_HA_FC_2400: btype = "2422"; break; case ISP_HA_FC_2500: btype = "2532"; break; default: break; } if (!IS_24XX(isp)) { /* * While we're paused, reset the FPM module and FBM * fifos. */ ISP_WRITE(isp, BIU2100_CSR, BIU2100_FPM0_REGS); ISP_WRITE(isp, FPM_DIAG_CONFIG, FPM_SOFT_RESET); ISP_WRITE(isp, BIU2100_CSR, BIU2100_FB_REGS); ISP_WRITE(isp, FBM_CMD, FBMCMD_FIFO_RESET_ALL); ISP_WRITE(isp, BIU2100_CSR, BIU2100_RISC_REGS); } } else if (IS_1240(isp)) { sdparam *sdp; btype = "1240"; isp->isp_clock = 60; sdp = SDPARAM(isp, 0); sdp->isp_ultramode = 1; sdp = SDPARAM(isp, 1); sdp->isp_ultramode = 1; /* * XXX: Should probably do some bus sensing. */ } else if (IS_ULTRA3(isp)) { sdparam *sdp = isp->isp_param; isp->isp_clock = 100; if (IS_10160(isp)) btype = "10160"; else if (IS_12160(isp)) btype = "12160"; else btype = ""; sdp->isp_lvdmode = 1; if (IS_DUALBUS(isp)) { sdp++; sdp->isp_lvdmode = 1; } } else if (IS_ULTRA2(isp)) { static const char m[] = "bus %d is in %s Mode"; uint16_t l; sdparam *sdp = SDPARAM(isp, 0); isp->isp_clock = 100; if (IS_1280(isp)) btype = "1280"; else if (IS_1080(isp)) btype = "1080"; else btype = ""; l = ISP_READ(isp, SXP_PINS_DIFF) & ISP1080_MODE_MASK; switch (l) { case ISP1080_LVD_MODE: sdp->isp_lvdmode = 1; isp_prt(isp, ISP_LOGCONFIG, m, 0, "LVD"); break; case ISP1080_HVD_MODE: sdp->isp_diffmode = 1; isp_prt(isp, ISP_LOGCONFIG, m, 0, "Differential"); break; case ISP1080_SE_MODE: sdp->isp_ultramode = 1; isp_prt(isp, ISP_LOGCONFIG, m, 0, "Single-Ended"); break; default: isp_prt(isp, ISP_LOGERR, "unknown mode on bus %d (0x%x)", 0, l); break; } if (IS_DUALBUS(isp)) { sdp = SDPARAM(isp, 1); l = ISP_READ(isp, SXP_PINS_DIFF|SXP_BANK1_SELECT); l &= ISP1080_MODE_MASK; switch (l) { case ISP1080_LVD_MODE: sdp->isp_lvdmode = 1; isp_prt(isp, ISP_LOGCONFIG, m, 1, "LVD"); break; case ISP1080_HVD_MODE: sdp->isp_diffmode = 1; isp_prt(isp, ISP_LOGCONFIG, m, 1, "Differential"); break; case ISP1080_SE_MODE: sdp->isp_ultramode = 1; isp_prt(isp, ISP_LOGCONFIG, m, 1, "Single-Ended"); break; default: isp_prt(isp, ISP_LOGERR, "unknown mode on bus %d (0x%x)", 1, l); break; } } } else { sdparam *sdp = SDPARAM(isp, 0); i = ISP_READ(isp, BIU_CONF0) & BIU_CONF0_HW_MASK; switch (i) { default: isp_prt(isp, ISP_LOGALL, "Unknown Chip Type 0x%x", i); /* FALLTHROUGH */ case 1: btype = "1020"; isp->isp_type = ISP_HA_SCSI_1020; isp->isp_clock = 40; break; case 2: /* * Some 1020A chips are Ultra Capable, but don't * run the clock rate up for that unless told to * do so by the Ultra Capable bits being set. */ btype = "1020A"; isp->isp_type = ISP_HA_SCSI_1020A; isp->isp_clock = 40; break; case 3: btype = "1040"; isp->isp_type = ISP_HA_SCSI_1040; isp->isp_clock = 60; break; case 4: btype = "1040A"; isp->isp_type = ISP_HA_SCSI_1040A; isp->isp_clock = 60; break; case 5: btype = "1040B"; isp->isp_type = ISP_HA_SCSI_1040B; isp->isp_clock = 60; break; case 6: btype = "1040C"; isp->isp_type = ISP_HA_SCSI_1040C; isp->isp_clock = 60; break; } /* * Now, while we're at it, gather info about ultra * and/or differential mode. */ if (ISP_READ(isp, SXP_PINS_DIFF) & SXP_PINS_DIFF_MODE) { isp_prt(isp, ISP_LOGCONFIG, "Differential Mode"); sdp->isp_diffmode = 1; } else { sdp->isp_diffmode = 0; } i = ISP_READ(isp, RISC_PSR); if (isp->isp_bustype == ISP_BT_SBUS) { i &= RISC_PSR_SBUS_ULTRA; } else { i &= RISC_PSR_PCI_ULTRA; } if (i != 0) { isp_prt(isp, ISP_LOGCONFIG, "Ultra Mode Capable"); sdp->isp_ultramode = 1; /* * If we're in Ultra Mode, we have to be 60MHz clock- * even for the SBus version. */ isp->isp_clock = 60; } else { sdp->isp_ultramode = 0; /* * Clock is known. Gronk. */ } /* * Machine dependent clock (if set) overrides * our generic determinations. */ if (isp->isp_mdvec->dv_clock) { if (isp->isp_mdvec->dv_clock < isp->isp_clock) { isp->isp_clock = isp->isp_mdvec->dv_clock; } } } /* * Clear instrumentation */ isp->isp_intcnt = isp->isp_intbogus = 0; /* * Do MD specific pre initialization */ ISP_RESET0(isp); /* * Hit the chip over the head with hammer, * and give it a chance to recover. */ if (IS_SCSI(isp)) { ISP_WRITE(isp, BIU_ICR, BIU_ICR_SOFT_RESET); /* * A slight delay... */ ISP_DELAY(100); /* * Clear data && control DMA engines. */ ISP_WRITE(isp, CDMA_CONTROL, DMA_CNTRL_CLEAR_CHAN | DMA_CNTRL_RESET_INT); ISP_WRITE(isp, DDMA_CONTROL, DMA_CNTRL_CLEAR_CHAN | DMA_CNTRL_RESET_INT); } else if (IS_24XX(isp)) { /* * Stop DMA and wait for it to stop. */ ISP_WRITE(isp, BIU2400_CSR, BIU2400_DMA_STOP|(3 << 4)); for (val = loops = 0; loops < 30000; loops++) { ISP_DELAY(10); val = ISP_READ(isp, BIU2400_CSR); if ((val & BIU2400_DMA_ACTIVE) == 0) { break; } } if (val & BIU2400_DMA_ACTIVE) { ISP_RESET0(isp); isp_prt(isp, ISP_LOGERR, "DMA Failed to Stop on Reset"); return; } /* * Hold it in SOFT_RESET and STOP state for 100us. */ ISP_WRITE(isp, BIU2400_CSR, BIU2400_SOFT_RESET|BIU2400_DMA_STOP|(3 << 4)); ISP_DELAY(100); for (loops = 0; loops < 10000; loops++) { ISP_DELAY(5); val = ISP_READ(isp, OUTMAILBOX0); } for (val = loops = 0; loops < 500000; loops ++) { val = ISP_READ(isp, BIU2400_CSR); if ((val & BIU2400_SOFT_RESET) == 0) { break; } } if (val & BIU2400_SOFT_RESET) { ISP_RESET0(isp); isp_prt(isp, ISP_LOGERR, "Failed to come out of reset"); return; } } else { ISP_WRITE(isp, BIU2100_CSR, BIU2100_SOFT_RESET); /* * A slight delay... */ ISP_DELAY(100); /* * Clear data && control DMA engines. */ ISP_WRITE(isp, CDMA2100_CONTROL, DMA_CNTRL2100_CLEAR_CHAN | DMA_CNTRL2100_RESET_INT); ISP_WRITE(isp, TDMA2100_CONTROL, DMA_CNTRL2100_CLEAR_CHAN | DMA_CNTRL2100_RESET_INT); ISP_WRITE(isp, RDMA2100_CONTROL, DMA_CNTRL2100_CLEAR_CHAN | DMA_CNTRL2100_RESET_INT); } /* * Wait for ISP to be ready to go... */ loops = MBOX_DELAY_COUNT; for (;;) { if (IS_SCSI(isp)) { if (!(ISP_READ(isp, BIU_ICR) & BIU_ICR_SOFT_RESET)) { break; } } else if (IS_24XX(isp)) { if (ISP_READ(isp, OUTMAILBOX0) == 0) { break; } } else { if (!(ISP_READ(isp, BIU2100_CSR) & BIU2100_SOFT_RESET)) break; } ISP_DELAY(100); if (--loops < 0) { ISP_DUMPREGS(isp, "chip reset timed out"); ISP_RESET0(isp); return; } } /* * After we've fired this chip up, zero out the conf1 register * for SCSI adapters and other settings for the 2100. */ if (IS_SCSI(isp)) { ISP_WRITE(isp, BIU_CONF1, 0); } else if (!IS_24XX(isp)) { ISP_WRITE(isp, BIU2100_CSR, 0); } /* * Reset RISC Processor */ if (IS_24XX(isp)) { ISP_WRITE(isp, BIU2400_HCCR, HCCR_2400_CMD_RESET); ISP_WRITE(isp, BIU2400_HCCR, HCCR_2400_CMD_RELEASE); ISP_WRITE(isp, BIU2400_HCCR, HCCR_2400_CMD_CLEAR_RESET); } else { ISP_WRITE(isp, HCCR, HCCR_CMD_RESET); ISP_DELAY(100); ISP_WRITE(isp, BIU_SEMA, 0); } /* * Post-RISC Reset stuff. */ if (IS_24XX(isp)) { for (val = loops = 0; loops < 5000000; loops++) { ISP_DELAY(5); val = ISP_READ(isp, OUTMAILBOX0); if (val == 0) { break; } } if (val != 0) { ISP_RESET0(isp); isp_prt(isp, ISP_LOGERR, "reset didn't clear"); return; } } else if (IS_SCSI(isp)) { uint16_t tmp = isp->isp_mdvec->dv_conf1; /* * Busted FIFO. Turn off all but burst enables. */ if (isp->isp_type == ISP_HA_SCSI_1040A) { tmp &= BIU_BURST_ENABLE; } ISP_SETBITS(isp, BIU_CONF1, tmp); if (tmp & BIU_BURST_ENABLE) { ISP_SETBITS(isp, CDMA_CONF, DMA_ENABLE_BURST); ISP_SETBITS(isp, DDMA_CONF, DMA_ENABLE_BURST); } if (SDPARAM(isp, 0)->isp_ptisp) { if (SDPARAM(isp, 0)->isp_ultramode) { while (ISP_READ(isp, RISC_MTR) != 0x1313) { ISP_WRITE(isp, RISC_MTR, 0x1313); ISP_WRITE(isp, HCCR, HCCR_CMD_STEP); } } else { ISP_WRITE(isp, RISC_MTR, 0x1212); } /* * PTI specific register */ ISP_WRITE(isp, RISC_EMB, DUAL_BANK); } else { ISP_WRITE(isp, RISC_MTR, 0x1212); } ISP_WRITE(isp, HCCR, HCCR_CMD_RELEASE); } else { ISP_WRITE(isp, RISC_MTR2100, 0x1212); if (IS_2200(isp) || IS_23XX(isp)) { ISP_WRITE(isp, HCCR, HCCR_2X00_DISABLE_PARITY_PAUSE); } ISP_WRITE(isp, HCCR, HCCR_CMD_RELEASE); } ISP_WRITE(isp, isp->isp_rqstinrp, 0); ISP_WRITE(isp, isp->isp_rqstoutrp, 0); ISP_WRITE(isp, isp->isp_respinrp, 0); ISP_WRITE(isp, isp->isp_respoutrp, 0); if (IS_24XX(isp)) { ISP_WRITE(isp, BIU2400_PRI_REQINP, 0); ISP_WRITE(isp, BIU2400_PRI_REQOUTP, 0); ISP_WRITE(isp, BIU2400_ATIO_RSPINP, 0); ISP_WRITE(isp, BIU2400_ATIO_RSPOUTP, 0); } /* * Do MD specific post initialization */ ISP_RESET1(isp); /* * Wait for everything to finish firing up. * * Avoid doing this on early 2312s because you can generate a PCI * parity error (chip breakage). */ if (IS_2312(isp) && isp->isp_revision < 2) { ISP_DELAY(100); } else { loops = MBOX_DELAY_COUNT; while (ISP_READ(isp, OUTMAILBOX0) == MBOX_BUSY) { ISP_DELAY(100); if (--loops < 0) { ISP_RESET0(isp); isp_prt(isp, ISP_LOGERR, "MBOX_BUSY never cleared on reset"); return; } } } /* * Up until this point we've done everything by just reading or * setting registers. From this point on we rely on at least *some* * kind of firmware running in the card. */ /* * Do some sanity checking by running a NOP command. * If it succeeds, the ROM firmware is now running. */ ISP_MEMZERO(&mbs, sizeof (mbs)); mbs.param[0] = MBOX_NO_OP; mbs.logval = MBLOGALL; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { isp_prt(isp, ISP_LOGERR, "NOP command failed (%x)", mbs.param[0]); ISP_RESET0(isp); return; } /* * Do some operational tests */ if (IS_SCSI(isp) || IS_24XX(isp)) { ISP_MEMZERO(&mbs, sizeof (mbs)); mbs.param[0] = MBOX_MAILBOX_REG_TEST; mbs.param[1] = 0xdead; mbs.param[2] = 0xbeef; mbs.param[3] = 0xffff; mbs.param[4] = 0x1111; mbs.param[5] = 0xa5a5; mbs.param[6] = 0x0000; mbs.param[7] = 0x0000; mbs.logval = MBLOGALL; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { ISP_RESET0(isp); return; } if (mbs.param[1] != 0xdead || mbs.param[2] != 0xbeef || mbs.param[3] != 0xffff || mbs.param[4] != 0x1111 || mbs.param[5] != 0xa5a5) { ISP_RESET0(isp); isp_prt(isp, ISP_LOGERR, "Register Test Failed (0x%x 0x%x 0x%x 0x%x 0x%x)", mbs.param[1], mbs.param[2], mbs.param[3], mbs.param[4], mbs.param[5]); return; } } /* * Download new Firmware, unless requested not to do so. * This is made slightly trickier in some cases where the * firmware of the ROM revision is newer than the revision * compiled into the driver. So, where we used to compare * versions of our f/w and the ROM f/w, now we just see * whether we have f/w at all and whether a config flag * has disabled our download. */ if ((isp->isp_mdvec->dv_ispfw == NULL) || (isp->isp_confopts & ISP_CFG_NORELOAD)) { dodnld = 0; } if (IS_24XX(isp)) { code_org = ISP_CODE_ORG_2400; } else if (IS_23XX(isp)) { code_org = ISP_CODE_ORG_2300; } else { code_org = ISP_CODE_ORG; } if (dodnld && IS_24XX(isp)) { const uint32_t *ptr = isp->isp_mdvec->dv_ispfw; /* * Keep loading until we run out of f/w. */ code_org = ptr[2]; /* 1st load address is our start addr */ for (;;) { uint32_t la, wi, wl; isp_prt(isp, ISP_LOGDEBUG0, "load 0x%x words of code at load address 0x%x", ptr[3], ptr[2]); wi = 0; la = ptr[2]; wl = ptr[3]; while (wi < ptr[3]) { uint32_t *cp; uint32_t nw; nw = ISP_QUEUE_SIZE(RQUEST_QUEUE_LEN(isp)) >> 2; if (nw > wl) { nw = wl; } cp = isp->isp_rquest; for (i = 0; i < nw; i++) { ISP_IOXPUT_32(isp, ptr[wi++], &cp[i]); wl--; } MEMORYBARRIER(isp, SYNC_REQUEST, 0, ISP_QUEUE_SIZE(RQUEST_QUEUE_LEN(isp)), -1); ISP_MEMZERO(&mbs, sizeof (mbs)); if (la < 0x10000 && nw < 0x10000) { mbs.param[0] = MBOX_LOAD_RISC_RAM_2100; mbs.param[1] = la; mbs.param[2] = DMA_WD1(isp->isp_rquest_dma); mbs.param[3] = DMA_WD0(isp->isp_rquest_dma); mbs.param[4] = nw; mbs.param[6] = DMA_WD3(isp->isp_rquest_dma); mbs.param[7] = DMA_WD2(isp->isp_rquest_dma); } else { mbs.param[0] = MBOX_LOAD_RISC_RAM; mbs.param[1] = la; mbs.param[2] = DMA_WD1(isp->isp_rquest_dma); mbs.param[3] = DMA_WD0(isp->isp_rquest_dma); mbs.param[4] = nw >> 16; mbs.param[5] = nw; mbs.param[6] = DMA_WD3(isp->isp_rquest_dma); mbs.param[7] = DMA_WD2(isp->isp_rquest_dma); mbs.param[8] = la >> 16; } mbs.logval = MBLOGALL; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { isp_prt(isp, ISP_LOGERR, "F/W Risc Ram Load Failed"); ISP_RESET0(isp); return; } la += nw; } if (ptr[1] == 0) { break; } ptr += ptr[3]; } isp->isp_loaded_fw = 1; } else if (dodnld && IS_23XX(isp)) { const uint16_t *ptr = isp->isp_mdvec->dv_ispfw; uint16_t wi, wl, segno; uint32_t la; la = code_org; segno = 0; for (;;) { uint32_t nxtaddr; isp_prt(isp, ISP_LOGDEBUG0, "load 0x%x words of code at load address 0x%x", ptr[3], la); wi = 0; wl = ptr[3]; while (wi < ptr[3]) { uint16_t *cp; uint16_t nw; nw = ISP_QUEUE_SIZE(RQUEST_QUEUE_LEN(isp)) >> 1; if (nw > wl) { nw = wl; } if (nw > (1 << 15)) { nw = 1 << 15; } cp = isp->isp_rquest; for (i = 0; i < nw; i++) { ISP_IOXPUT_16(isp, ptr[wi++], &cp[i]); wl--; } MEMORYBARRIER(isp, SYNC_REQUEST, 0, ISP_QUEUE_SIZE(RQUEST_QUEUE_LEN(isp)), -1); ISP_MEMZERO(&mbs, sizeof (mbs)); if (la < 0x10000) { mbs.param[0] = MBOX_LOAD_RISC_RAM_2100; mbs.param[1] = la; mbs.param[2] = DMA_WD1(isp->isp_rquest_dma); mbs.param[3] = DMA_WD0(isp->isp_rquest_dma); mbs.param[4] = nw; mbs.param[6] = DMA_WD3(isp->isp_rquest_dma); mbs.param[7] = DMA_WD2(isp->isp_rquest_dma); } else { mbs.param[0] = MBOX_LOAD_RISC_RAM; mbs.param[1] = la; mbs.param[2] = DMA_WD1(isp->isp_rquest_dma); mbs.param[3] = DMA_WD0(isp->isp_rquest_dma); mbs.param[4] = nw; mbs.param[6] = DMA_WD3(isp->isp_rquest_dma); mbs.param[7] = DMA_WD2(isp->isp_rquest_dma); mbs.param[8] = la >> 16; } mbs.logval = MBLOGALL; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { isp_prt(isp, ISP_LOGERR, "F/W Risc Ram Load Failed"); ISP_RESET0(isp); return; } la += nw; } if (!IS_2322(isp)) { break; } if (++segno == 3) { break; } /* * If we're a 2322, the firmware actually comes in * three chunks. We loaded the first at the code_org * address. The other two chunks, which follow right * after each other in memory here, get loaded at * addresses specfied at offset 0x9..0xB. */ nxtaddr = ptr[3]; ptr = &ptr[nxtaddr]; la = ptr[5] | ((ptr[4] & 0x3f) << 16); } isp->isp_loaded_fw = 1; } else if (dodnld) { union { const uint16_t *cp; uint16_t *np; } ucd; ucd.cp = isp->isp_mdvec->dv_ispfw; isp->isp_mbxworkp = &ucd.np[1]; isp->isp_mbxwrk0 = ucd.np[3] - 1; isp->isp_mbxwrk1 = code_org + 1; ISP_MEMZERO(&mbs, sizeof (mbs)); mbs.param[0] = MBOX_WRITE_RAM_WORD; mbs.param[1] = code_org; mbs.param[2] = ucd.np[0]; mbs.logval = MBLOGNONE; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { isp_prt(isp, ISP_LOGERR, "F/W download failed at word %d", isp->isp_mbxwrk1 - code_org); ISP_RESET0(isp); return; } } else { isp->isp_loaded_fw = 0; isp_prt(isp, ISP_LOGDEBUG2, "skipping f/w download"); } /* * If we loaded firmware, verify its checksum */ if (isp->isp_loaded_fw) { ISP_MEMZERO(&mbs, sizeof (mbs)); mbs.param[0] = MBOX_VERIFY_CHECKSUM; if (IS_24XX(isp)) { mbs.param[1] = code_org >> 16; mbs.param[2] = code_org; } else { mbs.param[1] = code_org; } isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { isp_prt(isp, ISP_LOGERR, dcrc); ISP_RESET0(isp); return; } } /* * Now start it rolling. * * If we didn't actually download f/w, * we still need to (re)start it. */ MBSINIT(&mbs, MBOX_EXEC_FIRMWARE, MBLOGALL, 1000000); if (IS_24XX(isp)) { mbs.param[1] = code_org >> 16; mbs.param[2] = code_org; if (isp->isp_loaded_fw) { mbs.param[3] = 0; } else { mbs.param[3] = 1; } if (IS_25XX(isp)) { mbs.ibits |= 0x10; } } else if (IS_2322(isp)) { mbs.param[1] = code_org; if (isp->isp_loaded_fw) { mbs.param[2] = 0; } else { mbs.param[2] = 1; } } else { mbs.param[1] = code_org; } isp_mboxcmd(isp, &mbs); if (IS_2322(isp) || IS_24XX(isp)) { if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { ISP_RESET0(isp); return; } } /* * Give it a chance to finish starting up. * Give the 24XX more time. */ if (IS_24XX(isp)) { ISP_DELAY(500000); /* * Check to see if the 24XX firmware really started. */ if (mbs.param[1] == 0xdead) { isp_prt(isp, ISP_LOGERR, "f/w didn't *really* start"); ISP_RESET0(isp); return; } } else { ISP_DELAY(250000); if (IS_SCSI(isp)) { /* * Set CLOCK RATE, but only if asked to. */ if (isp->isp_clock) { mbs.param[0] = MBOX_SET_CLOCK_RATE; mbs.param[1] = isp->isp_clock; mbs.logval = MBLOGNONE; isp_mboxcmd(isp, &mbs); /* we will try not to care if this fails */ } } } /* * Ask the chip for the current firmware version. * This should prove that the new firmware is working. */ MBSINIT(&mbs, MBOX_ABOUT_FIRMWARE, MBLOGALL, 0); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { ISP_RESET0(isp); return; } /* * The SBus firmware that we are using apparently does not return * major, minor, micro revisions in the mailbox registers, which * is really, really, annoying. */ if (ISP_SBUS_SUPPORTED && isp->isp_bustype == ISP_BT_SBUS) { if (dodnld) { #ifdef ISP_TARGET_MODE isp->isp_fwrev[0] = 7; isp->isp_fwrev[1] = 55; #else isp->isp_fwrev[0] = 1; isp->isp_fwrev[1] = 37; #endif isp->isp_fwrev[2] = 0; } } else { isp->isp_fwrev[0] = mbs.param[1]; isp->isp_fwrev[1] = mbs.param[2]; isp->isp_fwrev[2] = mbs.param[3]; } isp_prt(isp, ISP_LOGCONFIG, "Board Type %s, Chip Revision 0x%x, %s F/W Revision %d.%d.%d", btype, isp->isp_revision, dodnld? "loaded" : "resident", isp->isp_fwrev[0], isp->isp_fwrev[1], isp->isp_fwrev[2]); if (IS_FC(isp)) { /* * We do not believe firmware attributes for 2100 code less * than 1.17.0, unless it's the firmware we specifically * are loading. * * Note that all 22XX and later f/w is greater than 1.X.0. */ if ((ISP_FW_OLDER_THAN(isp, 1, 17, 1))) { #ifdef USE_SMALLER_2100_FIRMWARE isp->isp_fwattr = ISP_FW_ATTR_SCCLUN; #else isp->isp_fwattr = 0; #endif } else { isp->isp_fwattr = mbs.param[6]; isp_prt(isp, ISP_LOGDEBUG0, "Firmware Attributes = 0x%x", mbs.param[6]); } } else { #ifndef ISP_TARGET_MODE isp->isp_fwattr = ISP_FW_ATTR_TMODE; #else isp->isp_fwattr = 0; #endif } if (!IS_24XX(isp)) { MBSINIT(&mbs, MBOX_GET_FIRMWARE_STATUS, MBLOGALL, 0); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { ISP_RESET0(isp); return; } if (isp->isp_maxcmds >= mbs.param[2]) { isp->isp_maxcmds = mbs.param[2]; } } isp_prt(isp, ISP_LOGCONFIG, "%d max I/O command limit set", isp->isp_maxcmds); /* * If we don't have Multi-ID f/w loaded, we need to restrict channels to one. * Only make this check for non-SCSI cards (I'm not sure firmware attributes * work for them). */ if (IS_FC(isp) && ISP_CAP_MULTI_ID(isp) == 0 && isp->isp_nchan > 1) { isp_prt(isp, ISP_LOGWARN, "non-MULTIID f/w loaded, only can enable 1 of %d channels", isp->isp_nchan); isp->isp_nchan = 1; } for (i = 0; i < isp->isp_nchan; i++) { isp_fw_state(isp, i); } if (isp->isp_dead) { isp_shutdown(isp); ISP_DISABLE_INTS(isp); return; } isp->isp_state = ISP_RESETSTATE; /* * Okay- now that we have new firmware running, we now (re)set our * notion of how many luns we support. This is somewhat tricky because * if we haven't loaded firmware, we sometimes do not have an easy way * of knowing how many luns we support. * * Expanded lun firmware gives you 32 luns for SCSI cards and * 16384 luns for Fibre Channel cards. * * It turns out that even for QLogic 2100s with ROM 1.10 and above * we do get a firmware attributes word returned in mailbox register 6. * * Because the lun is in a different position in the Request Queue * Entry structure for Fibre Channel with expanded lun firmware, we * can only support one lun (lun zero) when we don't know what kind * of firmware we're running. */ if (IS_SCSI(isp)) { if (dodnld) { if (IS_ULTRA2(isp) || IS_ULTRA3(isp)) { isp->isp_maxluns = 32; } else { isp->isp_maxluns = 8; } } else { isp->isp_maxluns = 8; } } else { if (ISP_CAP_SCCFW(isp)) { isp->isp_maxluns = 16384; } else { isp->isp_maxluns = 16; } } /* * We get some default values established. As a side * effect, NVRAM is read here (unless overriden by * a configuration flag). */ if (do_load_defaults) { if (IS_SCSI(isp)) { isp_setdfltsdparm(isp); } else { for (i = 0; i < isp->isp_nchan; i++) { isp_setdfltfcparm(isp, i); } } } } /* * Initialize Parameters of Hardware to a known state. * * Locks are held before coming here. */ void isp_init(ispsoftc_t *isp) { if (IS_FC(isp)) { if (IS_24XX(isp)) { isp_fibre_init_2400(isp); } else { isp_fibre_init(isp); } } else { isp_scsi_init(isp); } GET_NANOTIME(&isp->isp_init_time); } static void isp_scsi_init(ispsoftc_t *isp) { sdparam *sdp_chan0, *sdp_chan1; mbreg_t mbs; sdp_chan0 = SDPARAM(isp, 0); sdp_chan1 = sdp_chan0; if (IS_DUALBUS(isp)) { sdp_chan1 = SDPARAM(isp, 1); } /* First do overall per-card settings. */ /* * If we have fast memory timing enabled, turn it on. */ if (sdp_chan0->isp_fast_mttr) { ISP_WRITE(isp, RISC_MTR, 0x1313); } /* * Set Retry Delay and Count. * You set both channels at the same time. */ MBSINIT(&mbs, MBOX_SET_RETRY_COUNT, MBLOGALL, 0); mbs.param[1] = sdp_chan0->isp_retry_count; mbs.param[2] = sdp_chan0->isp_retry_delay; mbs.param[6] = sdp_chan1->isp_retry_count; mbs.param[7] = sdp_chan1->isp_retry_delay; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } /* * Set ASYNC DATA SETUP time. This is very important. */ MBSINIT(&mbs, MBOX_SET_ASYNC_DATA_SETUP_TIME, MBLOGALL, 0); mbs.param[1] = sdp_chan0->isp_async_data_setup; mbs.param[2] = sdp_chan1->isp_async_data_setup; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } /* * Set ACTIVE Negation State. */ MBSINIT(&mbs, MBOX_SET_ACT_NEG_STATE, MBLOGNONE, 0); mbs.param[1] = (sdp_chan0->isp_req_ack_active_neg << 4) | (sdp_chan0->isp_data_line_active_neg << 5); mbs.param[2] = (sdp_chan1->isp_req_ack_active_neg << 4) | (sdp_chan1->isp_data_line_active_neg << 5); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { isp_prt(isp, ISP_LOGERR, "failed to set active negation state (%d,%d), (%d,%d)", sdp_chan0->isp_req_ack_active_neg, sdp_chan0->isp_data_line_active_neg, sdp_chan1->isp_req_ack_active_neg, sdp_chan1->isp_data_line_active_neg); /* * But don't return. */ } /* * Set the Tag Aging limit */ MBSINIT(&mbs, MBOX_SET_TAG_AGE_LIMIT, MBLOGALL, 0); mbs.param[1] = sdp_chan0->isp_tag_aging; mbs.param[2] = sdp_chan1->isp_tag_aging; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { isp_prt(isp, ISP_LOGERR, "failed to set tag age limit (%d,%d)", sdp_chan0->isp_tag_aging, sdp_chan1->isp_tag_aging); return; } /* * Set selection timeout. */ MBSINIT(&mbs, MBOX_SET_SELECT_TIMEOUT, MBLOGALL, 0); mbs.param[1] = sdp_chan0->isp_selection_timeout; mbs.param[2] = sdp_chan1->isp_selection_timeout; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } /* now do per-channel settings */ isp_scsi_channel_init(isp, 0); if (IS_DUALBUS(isp)) isp_scsi_channel_init(isp, 1); /* * Now enable request/response queues */ if (IS_ULTRA2(isp) || IS_1240(isp)) { MBSINIT(&mbs, MBOX_INIT_RES_QUEUE_A64, MBLOGALL, 0); mbs.param[1] = RESULT_QUEUE_LEN(isp); mbs.param[2] = DMA_WD1(isp->isp_result_dma); mbs.param[3] = DMA_WD0(isp->isp_result_dma); mbs.param[4] = 0; mbs.param[6] = DMA_WD3(isp->isp_result_dma); mbs.param[7] = DMA_WD2(isp->isp_result_dma); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } isp->isp_residx = mbs.param[5]; MBSINIT(&mbs, MBOX_INIT_REQ_QUEUE_A64, MBLOGALL, 0); mbs.param[1] = RQUEST_QUEUE_LEN(isp); mbs.param[2] = DMA_WD1(isp->isp_rquest_dma); mbs.param[3] = DMA_WD0(isp->isp_rquest_dma); mbs.param[5] = 0; mbs.param[6] = DMA_WD3(isp->isp_result_dma); mbs.param[7] = DMA_WD2(isp->isp_result_dma); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } isp->isp_reqidx = isp->isp_reqodx = mbs.param[4]; } else { MBSINIT(&mbs, MBOX_INIT_RES_QUEUE, MBLOGALL, 0); mbs.param[1] = RESULT_QUEUE_LEN(isp); mbs.param[2] = DMA_WD1(isp->isp_result_dma); mbs.param[3] = DMA_WD0(isp->isp_result_dma); mbs.param[4] = 0; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } isp->isp_residx = mbs.param[5]; MBSINIT(&mbs, MBOX_INIT_REQ_QUEUE, MBLOGALL, 0); mbs.param[1] = RQUEST_QUEUE_LEN(isp); mbs.param[2] = DMA_WD1(isp->isp_rquest_dma); mbs.param[3] = DMA_WD0(isp->isp_rquest_dma); mbs.param[5] = 0; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } isp->isp_reqidx = isp->isp_reqodx = mbs.param[4]; } /* * Turn on LVD transitions for ULTRA2 or better and other features * * Now that we have 32 bit handles, don't do any fast posting * any more. For Ultra2/Ultra3 cards, we can turn on 32 bit RIO * operation or use fast posting. To be conservative, we'll only * do this for Ultra3 cards now because the other cards are so * rare for this author to find and test with. */ MBSINIT(&mbs, MBOX_SET_FW_FEATURES, MBLOGALL, 0); if (IS_ULTRA2(isp)) mbs.param[1] |= FW_FEATURE_LVD_NOTIFY; #ifdef ISP_NO_RIO if (IS_ULTRA3(isp)) mbs.param[1] |= FW_FEATURE_FAST_POST; #else if (IS_ULTRA3(isp)) mbs.param[1] |= FW_FEATURE_RIO_32BIT; #endif if (mbs.param[1] != 0) { uint16_t sfeat = mbs.param[1]; isp_mboxcmd(isp, &mbs); if (mbs.param[0] == MBOX_COMMAND_COMPLETE) { isp_prt(isp, ISP_LOGINFO, "Enabled FW features (0x%x)", sfeat); } } isp->isp_state = ISP_INITSTATE; } static void isp_scsi_channel_init(ispsoftc_t *isp, int chan) { sdparam *sdp; mbreg_t mbs; int tgt; sdp = SDPARAM(isp, chan); /* * Set (possibly new) Initiator ID. */ MBSINIT(&mbs, MBOX_SET_INIT_SCSI_ID, MBLOGALL, 0); mbs.param[1] = (chan << 7) | sdp->isp_initiator_id; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } isp_prt(isp, ISP_LOGINFO, "Chan %d Initiator ID is %d", chan, sdp->isp_initiator_id); /* * Set current per-target parameters to an initial safe minimum. */ for (tgt = 0; tgt < MAX_TARGETS; tgt++) { int lun; uint16_t sdf; if (sdp->isp_devparam[tgt].dev_enable == 0) { continue; } #ifndef ISP_TARGET_MODE sdf = sdp->isp_devparam[tgt].goal_flags; sdf &= DPARM_SAFE_DFLT; /* * It is not quite clear when this changed over so that * we could force narrow and async for 1000/1020 cards, * but assume that this is only the case for loaded * firmware. */ if (isp->isp_loaded_fw) { sdf |= DPARM_NARROW | DPARM_ASYNC; } #else /* * The !$*!)$!$)* f/w uses the same index into some * internal table to decide how to respond to negotiations, * so if we've said "let's be safe" for ID X, and ID X * selects *us*, the negotiations will back to 'safe' * (as in narrow/async). What the f/w *should* do is * use the initiator id settings to decide how to respond. */ sdp->isp_devparam[tgt].goal_flags = sdf = DPARM_DEFAULT; #endif MBSINIT(&mbs, MBOX_SET_TARGET_PARAMS, MBLOGNONE, 0); mbs.param[1] = (chan << 15) | (tgt << 8); mbs.param[2] = sdf; if ((sdf & DPARM_SYNC) == 0) { mbs.param[3] = 0; } else { mbs.param[3] = (sdp->isp_devparam[tgt].goal_offset << 8) | (sdp->isp_devparam[tgt].goal_period); } isp_prt(isp, ISP_LOGDEBUG0, "Initial Settings bus%d tgt%d flags 0x%x off 0x%x per 0x%x", chan, tgt, mbs.param[2], mbs.param[3] >> 8, mbs.param[3] & 0xff); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { sdf = DPARM_SAFE_DFLT; MBSINIT(&mbs, MBOX_SET_TARGET_PARAMS, MBLOGALL, 0); mbs.param[1] = (tgt << 8) | (chan << 15); mbs.param[2] = sdf; mbs.param[3] = 0; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { continue; } } /* * We don't update any information directly from the f/w * because we need to run at least one command to cause a * new state to be latched up. So, we just assume that we * converge to the values we just had set. * * Ensure that we don't believe tagged queuing is enabled yet. * It turns out that sometimes the ISP just ignores our * attempts to set parameters for devices that it hasn't * seen yet. */ sdp->isp_devparam[tgt].actv_flags = sdf & ~DPARM_TQING; for (lun = 0; lun < (int) isp->isp_maxluns; lun++) { MBSINIT(&mbs, MBOX_SET_DEV_QUEUE_PARAMS, MBLOGALL, 0); mbs.param[1] = (chan << 15) | (tgt << 8) | lun; mbs.param[2] = sdp->isp_max_queue_depth; mbs.param[3] = sdp->isp_devparam[tgt].exc_throttle; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { break; } } } for (tgt = 0; tgt < MAX_TARGETS; tgt++) { if (sdp->isp_devparam[tgt].dev_refresh) { sdp->sendmarker = 1; sdp->update = 1; break; } } } /* * Fibre Channel specific initialization. */ static void isp_fibre_init(ispsoftc_t *isp) { fcparam *fcp; isp_icb_t local, *icbp = &local; mbreg_t mbs; int ownloopid; /* * We only support one channel on non-24XX cards */ fcp = FCPARAM(isp, 0); if (fcp->role == ISP_ROLE_NONE) { isp->isp_state = ISP_INITSTATE; return; } ISP_MEMZERO(icbp, sizeof (*icbp)); icbp->icb_version = ICB_VERSION1; icbp->icb_fwoptions = fcp->isp_fwoptions; /* * Firmware Options are either retrieved from NVRAM or * are patched elsewhere. We check them for sanity here * and make changes based on board revision, but otherwise * let others decide policy. */ /* * If this is a 2100 < revision 5, we have to turn off FAIRNESS. */ if (IS_2100(isp) && isp->isp_revision < 5) { icbp->icb_fwoptions &= ~ICBOPT_FAIRNESS; } /* * We have to use FULL LOGIN even though it resets the loop too much * because otherwise port database entries don't get updated after * a LIP- this is a known f/w bug for 2100 f/w less than 1.17.0. */ if (!ISP_FW_NEWER_THAN(isp, 1, 17, 0)) { icbp->icb_fwoptions |= ICBOPT_FULL_LOGIN; } /* * Insist on Port Database Update Async notifications */ icbp->icb_fwoptions |= ICBOPT_PDBCHANGE_AE; /* * Make sure that target role reflects into fwoptions. */ if (fcp->role & ISP_ROLE_TARGET) { icbp->icb_fwoptions |= ICBOPT_TGT_ENABLE; } else { icbp->icb_fwoptions &= ~ICBOPT_TGT_ENABLE; } if (fcp->role & ISP_ROLE_INITIATOR) { icbp->icb_fwoptions &= ~ICBOPT_INI_DISABLE; } else { icbp->icb_fwoptions |= ICBOPT_INI_DISABLE; } icbp->icb_maxfrmlen = DEFAULT_FRAMESIZE(isp); if (icbp->icb_maxfrmlen < ICB_MIN_FRMLEN || icbp->icb_maxfrmlen > ICB_MAX_FRMLEN) { isp_prt(isp, ISP_LOGERR, "bad frame length (%d) from NVRAM- using %d", DEFAULT_FRAMESIZE(isp), ICB_DFLT_FRMLEN); icbp->icb_maxfrmlen = ICB_DFLT_FRMLEN; } icbp->icb_maxalloc = fcp->isp_maxalloc; if (icbp->icb_maxalloc < 1) { isp_prt(isp, ISP_LOGERR, "bad maximum allocation (%d)- using 16", fcp->isp_maxalloc); icbp->icb_maxalloc = 16; } icbp->icb_execthrottle = DEFAULT_EXEC_THROTTLE(isp); if (icbp->icb_execthrottle < 1) { isp_prt(isp, ISP_LOGERR, "bad execution throttle of %d- using %d", DEFAULT_EXEC_THROTTLE(isp), ICB_DFLT_THROTTLE); icbp->icb_execthrottle = ICB_DFLT_THROTTLE; } icbp->icb_retry_delay = fcp->isp_retry_delay; icbp->icb_retry_count = fcp->isp_retry_count; icbp->icb_hardaddr = fcp->isp_loopid; ownloopid = (isp->isp_confopts & ISP_CFG_OWNLOOPID) != 0; if (icbp->icb_hardaddr >= LOCAL_LOOP_LIM) { icbp->icb_hardaddr = 0; ownloopid = 0; } /* * Our life seems so much better with 2200s and later with * the latest f/w if we set Hard Address. */ if (ownloopid || ISP_FW_NEWER_THAN(isp, 2, 2, 5)) { icbp->icb_fwoptions |= ICBOPT_HARD_ADDRESS; } /* * Right now we just set extended options to prefer point-to-point * over loop based upon some soft config options. * * NB: for the 2300, ICBOPT_EXTENDED is required. */ if (IS_2200(isp) || IS_23XX(isp)) { icbp->icb_fwoptions |= ICBOPT_EXTENDED; /* * Prefer or force Point-To-Point instead Loop? */ switch (isp->isp_confopts & ISP_CFG_PORT_PREF) { case ISP_CFG_NPORT: icbp->icb_xfwoptions |= ICBXOPT_PTP_2_LOOP; break; case ISP_CFG_NPORT_ONLY: icbp->icb_xfwoptions |= ICBXOPT_PTP_ONLY; break; case ISP_CFG_LPORT_ONLY: icbp->icb_xfwoptions |= ICBXOPT_LOOP_ONLY; break; default: icbp->icb_xfwoptions |= ICBXOPT_LOOP_2_PTP; break; } if (IS_2200(isp)) { /* * We can't have Fast Posting any more- we now * have 32 bit handles. * * RIO seemed to have to much breakage. * * Just opt for safety. */ icbp->icb_xfwoptions &= ~ICBXOPT_RIO_16BIT; icbp->icb_fwoptions &= ~ICBOPT_FAST_POST; } else { /* * QLogic recommends that FAST Posting be turned * off for 23XX cards and instead allow the HBA * to write response queue entries and interrupt * after a delay (ZIO). */ icbp->icb_fwoptions &= ~ICBOPT_FAST_POST; if ((fcp->isp_xfwoptions & ICBXOPT_TIMER_MASK) == ICBXOPT_ZIO) { icbp->icb_xfwoptions |= ICBXOPT_ZIO; icbp->icb_idelaytimer = 10; } if (isp->isp_confopts & ISP_CFG_ONEGB) { icbp->icb_zfwoptions |= ICBZOPT_RATE_ONEGB; } else if (isp->isp_confopts & ISP_CFG_TWOGB) { icbp->icb_zfwoptions |= ICBZOPT_RATE_TWOGB; } else { icbp->icb_zfwoptions |= ICBZOPT_RATE_AUTO; } if (fcp->isp_zfwoptions & ICBZOPT_50_OHM) { icbp->icb_zfwoptions |= ICBZOPT_50_OHM; } } } /* * For 22XX > 2.1.26 && 23XX, set some options. */ if (ISP_FW_NEWER_THAN(isp, 2, 26, 0)) { MBSINIT(&mbs, MBOX_SET_FIRMWARE_OPTIONS, MBLOGALL, 0); mbs.param[1] = IFCOPT1_DISF7SWTCH|IFCOPT1_LIPASYNC|IFCOPT1_LIPF8; mbs.param[2] = 0; mbs.param[3] = 0; if (ISP_FW_NEWER_THAN(isp, 3, 16, 0)) { mbs.param[1] |= IFCOPT1_EQFQASYNC|IFCOPT1_CTIO_RETRY; if (fcp->role & ISP_ROLE_TARGET) { mbs.param[3] = IFCOPT3_NOPRLI; } } isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } } icbp->icb_logintime = ICB_LOGIN_TOV; icbp->icb_lunetimeout = ICB_LUN_ENABLE_TOV; if (fcp->isp_wwnn && fcp->isp_wwpn && (fcp->isp_wwnn >> 60) != 2) { icbp->icb_fwoptions |= ICBOPT_BOTH_WWNS; MAKE_NODE_NAME_FROM_WWN(icbp->icb_nodename, fcp->isp_wwnn); MAKE_NODE_NAME_FROM_WWN(icbp->icb_portname, fcp->isp_wwpn); isp_prt(isp, ISP_LOGDEBUG1, "Setting ICB Node 0x%08x%08x Port 0x%08x%08x", ((uint32_t) (fcp->isp_wwnn >> 32)), ((uint32_t) (fcp->isp_wwnn)), ((uint32_t) (fcp->isp_wwpn >> 32)), ((uint32_t) (fcp->isp_wwpn))); } else if (fcp->isp_wwpn) { icbp->icb_fwoptions &= ~ICBOPT_BOTH_WWNS; MAKE_NODE_NAME_FROM_WWN(icbp->icb_portname, fcp->isp_wwpn); isp_prt(isp, ISP_LOGDEBUG1, "Setting ICB Port 0x%08x%08x", ((uint32_t) (fcp->isp_wwpn >> 32)), ((uint32_t) (fcp->isp_wwpn))); } else { isp_prt(isp, ISP_LOGERR, "No valid WWNs to use"); return; } icbp->icb_rqstqlen = RQUEST_QUEUE_LEN(isp); if (icbp->icb_rqstqlen < 1) { isp_prt(isp, ISP_LOGERR, "bad request queue length"); } icbp->icb_rsltqlen = RESULT_QUEUE_LEN(isp); if (icbp->icb_rsltqlen < 1) { isp_prt(isp, ISP_LOGERR, "bad result queue length"); } icbp->icb_rqstaddr[RQRSP_ADDR0015] = DMA_WD0(isp->isp_rquest_dma); icbp->icb_rqstaddr[RQRSP_ADDR1631] = DMA_WD1(isp->isp_rquest_dma); icbp->icb_rqstaddr[RQRSP_ADDR3247] = DMA_WD2(isp->isp_rquest_dma); icbp->icb_rqstaddr[RQRSP_ADDR4863] = DMA_WD3(isp->isp_rquest_dma); icbp->icb_respaddr[RQRSP_ADDR0015] = DMA_WD0(isp->isp_result_dma); icbp->icb_respaddr[RQRSP_ADDR1631] = DMA_WD1(isp->isp_result_dma); icbp->icb_respaddr[RQRSP_ADDR3247] = DMA_WD2(isp->isp_result_dma); icbp->icb_respaddr[RQRSP_ADDR4863] = DMA_WD3(isp->isp_result_dma); if (FC_SCRATCH_ACQUIRE(isp, 0)) { isp_prt(isp, ISP_LOGERR, sacq); return; } isp_prt(isp, ISP_LOGDEBUG0, "isp_fibre_init: fwopt 0x%x xfwopt 0x%x zfwopt 0x%x", icbp->icb_fwoptions, icbp->icb_xfwoptions, icbp->icb_zfwoptions); isp_put_icb(isp, icbp, (isp_icb_t *)fcp->isp_scratch); /* * Init the firmware */ MBSINIT(&mbs, MBOX_INIT_FIRMWARE, MBLOGALL, 30000000); mbs.param[2] = DMA_WD1(fcp->isp_scdma); mbs.param[3] = DMA_WD0(fcp->isp_scdma); mbs.param[6] = DMA_WD3(fcp->isp_scdma); mbs.param[7] = DMA_WD2(fcp->isp_scdma); mbs.logval = MBLOGALL; isp_prt(isp, ISP_LOGDEBUG0, "INIT F/W from %p (%08x%08x)", fcp->isp_scratch, (uint32_t) ((uint64_t)fcp->isp_scdma >> 32), (uint32_t) fcp->isp_scdma); MEMORYBARRIER(isp, SYNC_SFORDEV, 0, sizeof (*icbp), 0); isp_mboxcmd(isp, &mbs); FC_SCRATCH_RELEASE(isp, 0); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { isp_print_bytes(isp, "isp_fibre_init", sizeof (*icbp), icbp); return; } isp->isp_reqidx = 0; isp->isp_reqodx = 0; isp->isp_residx = 0; /* * Whatever happens, we're now committed to being here. */ isp->isp_state = ISP_INITSTATE; } static void isp_fibre_init_2400(ispsoftc_t *isp) { fcparam *fcp; isp_icb_2400_t local, *icbp = &local; mbreg_t mbs; int chan; /* * Check to see whether all channels have *some* kind of role */ for (chan = 0; chan < isp->isp_nchan; chan++) { fcp = FCPARAM(isp, chan); if (fcp->role != ISP_ROLE_NONE) { break; } } if (chan == isp->isp_nchan) { isp_prt(isp, ISP_LOGDEBUG0, "all %d channels with role 'none'", chan); isp->isp_state = ISP_INITSTATE; return; } /* * Start with channel 0. */ fcp = FCPARAM(isp, 0); /* * Turn on LIP F8 async event (1) */ MBSINIT(&mbs, MBOX_SET_FIRMWARE_OPTIONS, MBLOGALL, 0); mbs.param[1] = 1; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } ISP_MEMZERO(icbp, sizeof (*icbp)); icbp->icb_fwoptions1 = fcp->isp_fwoptions; if (fcp->role & ISP_ROLE_TARGET) { icbp->icb_fwoptions1 |= ICB2400_OPT1_TGT_ENABLE; } else { icbp->icb_fwoptions1 &= ~ICB2400_OPT1_TGT_ENABLE; } if (fcp->role & ISP_ROLE_INITIATOR) { icbp->icb_fwoptions1 &= ~ICB2400_OPT1_INI_DISABLE; } else { icbp->icb_fwoptions1 |= ICB2400_OPT1_INI_DISABLE; } icbp->icb_version = ICB_VERSION1; icbp->icb_maxfrmlen = DEFAULT_FRAMESIZE(isp); if (icbp->icb_maxfrmlen < ICB_MIN_FRMLEN || icbp->icb_maxfrmlen > ICB_MAX_FRMLEN) { isp_prt(isp, ISP_LOGERR, "bad frame length (%d) from NVRAM- using %d", DEFAULT_FRAMESIZE(isp), ICB_DFLT_FRMLEN); icbp->icb_maxfrmlen = ICB_DFLT_FRMLEN; } icbp->icb_execthrottle = DEFAULT_EXEC_THROTTLE(isp); if (icbp->icb_execthrottle < 1) { isp_prt(isp, ISP_LOGERR, "bad execution throttle of %d- using %d", DEFAULT_EXEC_THROTTLE(isp), ICB_DFLT_THROTTLE); icbp->icb_execthrottle = ICB_DFLT_THROTTLE; } if (icbp->icb_fwoptions1 & ICB2400_OPT1_TGT_ENABLE) { /* * Get current resource count */ MBSINIT(&mbs, MBOX_GET_RESOURCE_COUNT, MBLOGALL, 0); mbs.obits = 0x4cf; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } icbp->icb_xchgcnt = mbs.param[3]; } icbp->icb_hardaddr = fcp->isp_loopid; if (icbp->icb_hardaddr >= LOCAL_LOOP_LIM) { icbp->icb_hardaddr = 0; } /* * Force this on. */ icbp->icb_fwoptions1 |= ICB2400_OPT1_HARD_ADDRESS; icbp->icb_fwoptions2 = fcp->isp_xfwoptions; switch (isp->isp_confopts & ISP_CFG_PORT_PREF) { #if 0 case ISP_CFG_NPORT: /* * XXX: This causes the f/w to crash. */ icbp->icb_fwoptions2 &= ~ICB2400_OPT2_TOPO_MASK; icbp->icb_fwoptions2 |= ICB2400_OPT2_PTP_2_LOOP; break; #endif case ISP_CFG_NPORT_ONLY: icbp->icb_fwoptions2 &= ~ICB2400_OPT2_TOPO_MASK; icbp->icb_fwoptions2 |= ICB2400_OPT2_PTP_ONLY; break; case ISP_CFG_LPORT_ONLY: icbp->icb_fwoptions2 &= ~ICB2400_OPT2_TOPO_MASK; icbp->icb_fwoptions2 |= ICB2400_OPT2_LOOP_ONLY; break; default: icbp->icb_fwoptions2 &= ~ICB2400_OPT2_TOPO_MASK; icbp->icb_fwoptions2 |= ICB2400_OPT2_LOOP_2_PTP; break; } /* force this on for now */ icbp->icb_fwoptions2 |= ICB2400_OPT2_ZIO; switch (icbp->icb_fwoptions2 & ICB2400_OPT2_TIMER_MASK) { case ICB2400_OPT2_ZIO: case ICB2400_OPT2_ZIO1: icbp->icb_idelaytimer = 0; break; case 0: break; default: isp_prt(isp, ISP_LOGWARN, "bad value %x in fwopt2 timer field", icbp->icb_fwoptions2 & ICB2400_OPT2_TIMER_MASK); icbp->icb_fwoptions2 &= ~ICB2400_OPT2_TIMER_MASK; break; } /* * We don't support FCTAPE, so clear it. */ icbp->icb_fwoptions2 &= ~ICB2400_OPT2_FCTAPE; icbp->icb_fwoptions3 = fcp->isp_zfwoptions; icbp->icb_fwoptions3 &= ~ICB2400_OPT3_RATE_AUTO; if (isp->isp_confopts & ISP_CFG_ONEGB) { icbp->icb_fwoptions3 |= ICB2400_OPT3_RATE_ONEGB; } else if (isp->isp_confopts & ISP_CFG_TWOGB) { icbp->icb_fwoptions3 |= ICB2400_OPT3_RATE_TWOGB; } else if (isp->isp_confopts & ISP_CFG_FOURGB) { icbp->icb_fwoptions3 |= ICB2400_OPT3_RATE_FOURGB; } else { icbp->icb_fwoptions3 |= ICB2400_OPT3_RATE_AUTO; } if ((isp->isp_confopts & ISP_CFG_OWNLOOPID) == 0) { icbp->icb_fwoptions3 |= ICB2400_OPT3_SOFTID; } icbp->icb_logintime = ICB_LOGIN_TOV; if (fcp->isp_wwnn && fcp->isp_wwpn && (fcp->isp_wwnn >> 60) != 2) { icbp->icb_fwoptions1 |= ICB2400_OPT1_BOTH_WWNS; MAKE_NODE_NAME_FROM_WWN(icbp->icb_portname, fcp->isp_wwpn); MAKE_NODE_NAME_FROM_WWN(icbp->icb_nodename, fcp->isp_wwnn); isp_prt(isp, ISP_LOGDEBUG1, "Setting ICB Node 0x%08x%08x Port 0x%08x%08x", ((uint32_t) (fcp->isp_wwnn >> 32)), ((uint32_t) (fcp->isp_wwnn)), ((uint32_t) (fcp->isp_wwpn >> 32)), ((uint32_t) (fcp->isp_wwpn))); } else if (fcp->isp_wwpn) { icbp->icb_fwoptions1 &= ~ICB2400_OPT1_BOTH_WWNS; MAKE_NODE_NAME_FROM_WWN(icbp->icb_portname, fcp->isp_wwpn); isp_prt(isp, ISP_LOGDEBUG1, "Setting ICB Node to be same as Port 0x%08x%08x", ((uint32_t) (fcp->isp_wwpn >> 32)), ((uint32_t) (fcp->isp_wwpn))); } else { isp_prt(isp, ISP_LOGERR, "No valid WWNs to use"); return; } icbp->icb_retry_count = fcp->isp_retry_count; icbp->icb_rqstqlen = RQUEST_QUEUE_LEN(isp); if (icbp->icb_rqstqlen < 8) { isp_prt(isp, ISP_LOGERR, "bad request queue length %d", icbp->icb_rqstqlen); return; } icbp->icb_rsltqlen = RESULT_QUEUE_LEN(isp); if (icbp->icb_rsltqlen < 8) { isp_prt(isp, ISP_LOGERR, "bad result queue length %d", icbp->icb_rsltqlen); return; } icbp->icb_rqstaddr[RQRSP_ADDR0015] = DMA_WD0(isp->isp_rquest_dma); icbp->icb_rqstaddr[RQRSP_ADDR1631] = DMA_WD1(isp->isp_rquest_dma); icbp->icb_rqstaddr[RQRSP_ADDR3247] = DMA_WD2(isp->isp_rquest_dma); icbp->icb_rqstaddr[RQRSP_ADDR4863] = DMA_WD3(isp->isp_rquest_dma); icbp->icb_respaddr[RQRSP_ADDR0015] = DMA_WD0(isp->isp_result_dma); icbp->icb_respaddr[RQRSP_ADDR1631] = DMA_WD1(isp->isp_result_dma); icbp->icb_respaddr[RQRSP_ADDR3247] = DMA_WD2(isp->isp_result_dma); icbp->icb_respaddr[RQRSP_ADDR4863] = DMA_WD3(isp->isp_result_dma); #ifdef ISP_TARGET_MODE /* unconditionally set up the ATIO queue if we support target mode */ icbp->icb_atioqlen = RESULT_QUEUE_LEN(isp); if (icbp->icb_atioqlen < 8) { isp_prt(isp, ISP_LOGERR, "bad ATIO queue length %d", icbp->icb_atioqlen); return; } icbp->icb_atioqaddr[RQRSP_ADDR0015] = DMA_WD0(isp->isp_atioq_dma); icbp->icb_atioqaddr[RQRSP_ADDR1631] = DMA_WD1(isp->isp_atioq_dma); icbp->icb_atioqaddr[RQRSP_ADDR3247] = DMA_WD2(isp->isp_atioq_dma); icbp->icb_atioqaddr[RQRSP_ADDR4863] = DMA_WD3(isp->isp_atioq_dma); isp_prt(isp, ISP_LOGDEBUG0, "isp_fibre_init_2400: atioq %04x%04x%04x%04x", DMA_WD3(isp->isp_atioq_dma), DMA_WD2(isp->isp_atioq_dma), DMA_WD1(isp->isp_atioq_dma), DMA_WD0(isp->isp_atioq_dma)); #endif isp_prt(isp, ISP_LOGDEBUG0, "isp_fibre_init_2400: fwopt1 0x%x fwopt2 0x%x fwopt3 0x%x", icbp->icb_fwoptions1, icbp->icb_fwoptions2, icbp->icb_fwoptions3); isp_prt(isp, ISP_LOGDEBUG0, "isp_fibre_init_2400: rqst %04x%04x%04x%04x rsp %04x%04x%04x%04x", DMA_WD3(isp->isp_rquest_dma), DMA_WD2(isp->isp_rquest_dma), DMA_WD1(isp->isp_rquest_dma), DMA_WD0(isp->isp_rquest_dma), DMA_WD3(isp->isp_result_dma), DMA_WD2(isp->isp_result_dma), DMA_WD1(isp->isp_result_dma), DMA_WD0(isp->isp_result_dma)); if (isp->isp_dblev & ISP_LOGDEBUG1) { isp_print_bytes(isp, "isp_fibre_init_2400", sizeof (*icbp), icbp); } if (FC_SCRATCH_ACQUIRE(isp, 0)) { isp_prt(isp, ISP_LOGERR, sacq); return; } ISP_MEMZERO(fcp->isp_scratch, ISP_FC_SCRLEN); isp_put_icb_2400(isp, icbp, fcp->isp_scratch); /* * Now fill in information about any additional channels */ if (isp->isp_nchan > 1) { isp_icb_2400_vpinfo_t vpinfo, *vdst; vp_port_info_t pi, *pdst; size_t amt = 0; uint8_t *off; vpinfo.vp_count = isp->isp_nchan - 1; vpinfo.vp_global_options = 0; off = fcp->isp_scratch; off += ICB2400_VPINFO_OFF; vdst = (isp_icb_2400_vpinfo_t *) off; isp_put_icb_2400_vpinfo(isp, &vpinfo, vdst); amt = ICB2400_VPINFO_OFF + sizeof (isp_icb_2400_vpinfo_t); for (chan = 1; chan < isp->isp_nchan; chan++) { fcparam *fcp2; ISP_MEMZERO(&pi, sizeof (pi)); fcp2 = FCPARAM(isp, chan); if (fcp2->role != ISP_ROLE_NONE) { pi.vp_port_options = ICB2400_VPOPT_ENABLED; if (fcp2->role & ISP_ROLE_INITIATOR) { pi.vp_port_options |= ICB2400_VPOPT_INI_ENABLE; } if ((fcp2->role & ISP_ROLE_TARGET) == 0) { pi.vp_port_options |= ICB2400_VPOPT_TGT_DISABLE; } MAKE_NODE_NAME_FROM_WWN(pi.vp_port_portname, fcp2->isp_wwpn); MAKE_NODE_NAME_FROM_WWN(pi.vp_port_nodename, fcp2->isp_wwnn); } off = fcp->isp_scratch; off += ICB2400_VPINFO_PORT_OFF(chan); pdst = (vp_port_info_t *) off; isp_put_vp_port_info(isp, &pi, pdst); amt += ICB2400_VPOPT_WRITE_SIZE; } } /* * Init the firmware */ MBSINIT(&mbs, 0, MBLOGALL, 30000000); if (isp->isp_nchan > 1) { mbs.param[0] = MBOX_INIT_FIRMWARE_MULTI_ID; } else { mbs.param[0] = MBOX_INIT_FIRMWARE; } mbs.param[2] = DMA_WD1(fcp->isp_scdma); mbs.param[3] = DMA_WD0(fcp->isp_scdma); mbs.param[6] = DMA_WD3(fcp->isp_scdma); mbs.param[7] = DMA_WD2(fcp->isp_scdma); isp_prt(isp, ISP_LOGDEBUG0, "INIT F/W from %04x%04x%04x%04x", DMA_WD3(fcp->isp_scdma), DMA_WD2(fcp->isp_scdma), DMA_WD1(fcp->isp_scdma), DMA_WD0(fcp->isp_scdma)); MEMORYBARRIER(isp, SYNC_SFORDEV, 0, sizeof (*icbp), 0); isp_mboxcmd(isp, &mbs); FC_SCRATCH_RELEASE(isp, 0); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return; } isp->isp_reqidx = 0; isp->isp_reqodx = 0; isp->isp_residx = 0; /* * Whatever happens, we're now committed to being here. */ isp->isp_state = ISP_INITSTATE; } static void isp_mark_portdb(ispsoftc_t *isp, int chan, int disposition) { fcparam *fcp = FCPARAM(isp, chan); int i; if (chan < 0 || chan >= isp->isp_nchan) { isp_prt(isp, ISP_LOGWARN, "isp_mark_portdb: bad channel %d", chan); return; } for (i = 0; i < MAX_FC_TARG; i++) { if (fcp->portdb[i].target_mode) { if (disposition < 0) { isp_prt(isp, ISP_LOGTINFO, "isp_mark_portdb: Chan %d zeroing handle 0x" "%04x port 0x%06x", chan, fcp->portdb[i].handle, fcp->portdb[i].portid); ISP_MEMZERO(&fcp->portdb[i], sizeof (fcportdb_t)); } continue; } if (disposition == 0) { ISP_MEMZERO(&fcp->portdb[i], sizeof (fcportdb_t)); } else { switch (fcp->portdb[i].state) { case FC_PORTDB_STATE_CHANGED: case FC_PORTDB_STATE_PENDING_VALID: case FC_PORTDB_STATE_VALID: case FC_PORTDB_STATE_PROBATIONAL: fcp->portdb[i].state = FC_PORTDB_STATE_PROBATIONAL; break; case FC_PORTDB_STATE_ZOMBIE: break; case FC_PORTDB_STATE_NIL: default: ISP_MEMZERO(&fcp->portdb[i], sizeof (fcportdb_t)); fcp->portdb[i].state = FC_PORTDB_STATE_NIL; break; } } } } /* * Perform an IOCB PLOGI or LOGO via EXECUTE IOCB A64 for 24XX cards * or via FABRIC LOGIN/FABRIC LOGOUT for other cards. */ static int isp_plogx(ispsoftc_t *isp, int chan, uint16_t handle, uint32_t portid, int flags, int gs) { mbreg_t mbs; uint8_t q[QENTRY_LEN]; isp_plogx_t *plp; fcparam *fcp; uint8_t *scp; uint32_t sst, parm1; int rval, lev; const char *msg; char buf[64]; if (!IS_24XX(isp)) { int action = flags & PLOGX_FLG_CMD_MASK; if (action == PLOGX_FLG_CMD_PLOGI) { return (isp_port_login(isp, handle, portid)); } else if (action == PLOGX_FLG_CMD_LOGO) { return (isp_port_logout(isp, handle, portid)); } else { return (MBOX_INVALID_COMMAND); } } ISP_MEMZERO(q, QENTRY_LEN); plp = (isp_plogx_t *) q; plp->plogx_header.rqs_entry_count = 1; plp->plogx_header.rqs_entry_type = RQSTYPE_LOGIN; plp->plogx_handle = 0xffffffff; plp->plogx_nphdl = handle; plp->plogx_vphdl = chan; plp->plogx_portlo = portid; plp->plogx_rspsz_porthi = (portid >> 16) & 0xff; plp->plogx_flags = flags; if (isp->isp_dblev & ISP_LOGDEBUG1) { isp_print_bytes(isp, "IOCB LOGX", QENTRY_LEN, plp); } if (gs == 0) { if (FC_SCRATCH_ACQUIRE(isp, chan)) { isp_prt(isp, ISP_LOGERR, sacq); return (-1); } } fcp = FCPARAM(isp, chan); scp = fcp->isp_scratch; isp_put_plogx(isp, plp, (isp_plogx_t *) scp); MBSINIT(&mbs, MBOX_EXEC_COMMAND_IOCB_A64, MBLOGALL, 500000); mbs.param[1] = QENTRY_LEN; mbs.param[2] = DMA_WD1(fcp->isp_scdma); mbs.param[3] = DMA_WD0(fcp->isp_scdma); mbs.param[6] = DMA_WD3(fcp->isp_scdma); mbs.param[7] = DMA_WD2(fcp->isp_scdma); MEMORYBARRIER(isp, SYNC_SFORDEV, 0, QENTRY_LEN, chan); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { rval = mbs.param[0]; goto out; } MEMORYBARRIER(isp, SYNC_SFORCPU, QENTRY_LEN, QENTRY_LEN, chan); scp += QENTRY_LEN; isp_get_plogx(isp, (isp_plogx_t *) scp, plp); if (isp->isp_dblev & ISP_LOGDEBUG1) { isp_print_bytes(isp, "IOCB LOGX response", QENTRY_LEN, plp); } if (plp->plogx_status == PLOGX_STATUS_OK) { rval = 0; goto out; } else if (plp->plogx_status != PLOGX_STATUS_IOCBERR) { isp_prt(isp, ISP_LOGWARN, "status 0x%x on port login IOCB chanel %d", plp->plogx_status, chan); rval = -1; goto out; } sst = plp->plogx_ioparm[0].lo16 | (plp->plogx_ioparm[0].hi16 << 16); parm1 = plp->plogx_ioparm[1].lo16 | (plp->plogx_ioparm[1].hi16 << 16); rval = -1; lev = ISP_LOGERR; msg = NULL; switch (sst) { case PLOGX_IOCBERR_NOLINK: msg = "no link"; break; case PLOGX_IOCBERR_NOIOCB: msg = "no IOCB buffer"; break; case PLOGX_IOCBERR_NOXGHG: msg = "no Exchange Control Block"; break; case PLOGX_IOCBERR_FAILED: ISP_SNPRINTF(buf, sizeof (buf), "reason 0x%x (last LOGIN state 0x%x)", parm1 & 0xff, (parm1 >> 8) & 0xff); msg = buf; break; case PLOGX_IOCBERR_NOFABRIC: msg = "no fabric"; break; case PLOGX_IOCBERR_NOTREADY: msg = "firmware not ready"; break; case PLOGX_IOCBERR_NOLOGIN: ISP_SNPRINTF(buf, sizeof (buf), "not logged in (last state 0x%x)", parm1); msg = buf; rval = MBOX_NOT_LOGGED_IN; break; case PLOGX_IOCBERR_REJECT: ISP_SNPRINTF(buf, sizeof (buf), "LS_RJT = 0x%x", parm1); msg = buf; break; case PLOGX_IOCBERR_NOPCB: msg = "no PCB allocated"; break; case PLOGX_IOCBERR_EINVAL: ISP_SNPRINTF(buf, sizeof (buf), "invalid parameter at offset 0x%x", parm1); msg = buf; break; case PLOGX_IOCBERR_PORTUSED: lev = ISP_LOGSANCFG|ISP_LOGDEBUG0; ISP_SNPRINTF(buf, sizeof (buf), "already logged in with N-Port handle 0x%x", parm1); msg = buf; rval = MBOX_PORT_ID_USED | (parm1 << 16); break; case PLOGX_IOCBERR_HNDLUSED: lev = ISP_LOGSANCFG|ISP_LOGDEBUG0; ISP_SNPRINTF(buf, sizeof (buf), "handle already used for PortID 0x%06x", parm1); msg = buf; rval = MBOX_LOOP_ID_USED; break; case PLOGX_IOCBERR_NOHANDLE: msg = "no handle allocated"; break; case PLOGX_IOCBERR_NOFLOGI: msg = "no FLOGI_ACC"; break; default: ISP_SNPRINTF(buf, sizeof (buf), "status %x from %x", plp->plogx_status, flags); msg = buf; break; } if (msg) { isp_prt(isp, ISP_LOGERR, "Chan %d PLOGX PortID 0x%06x to N-Port handle 0x%x: %s", chan, portid, handle, msg); } out: if (gs == 0) { FC_SCRATCH_RELEASE(isp, chan); } return (rval); } static int isp_port_login(ispsoftc_t *isp, uint16_t handle, uint32_t portid) { mbreg_t mbs; MBSINIT(&mbs, MBOX_FABRIC_LOGIN, MBLOGNONE, 500000); if (ISP_CAP_2KLOGIN(isp)) { mbs.param[1] = handle; mbs.ibits = (1 << 10); } else { mbs.param[1] = handle << 8; } mbs.param[2] = portid >> 16; mbs.param[3] = portid; mbs.logval = MBLOGNONE; mbs.timeout = 500000; isp_mboxcmd(isp, &mbs); switch (mbs.param[0]) { case MBOX_PORT_ID_USED: isp_prt(isp, ISP_LOGDEBUG0, "isp_port_login: portid 0x%06x already logged in as %u", portid, mbs.param[1]); return (MBOX_PORT_ID_USED | (mbs.param[1] << 16)); case MBOX_LOOP_ID_USED: isp_prt(isp, ISP_LOGDEBUG0, "isp_port_login: handle 0x%04x in use for port id 0x%02xXXXX", handle, mbs.param[1] & 0xff); return (MBOX_LOOP_ID_USED); case MBOX_COMMAND_COMPLETE: return (0); case MBOX_COMMAND_ERROR: isp_prt(isp, ISP_LOGINFO, "isp_port_login: error 0x%x in PLOGI to port 0x%06x", mbs.param[1], portid); return (MBOX_COMMAND_ERROR); case MBOX_ALL_IDS_USED: isp_prt(isp, ISP_LOGINFO, "isp_port_login: all IDs used for fabric login"); return (MBOX_ALL_IDS_USED); default: isp_prt(isp, ISP_LOGINFO, "isp_port_login: error 0x%x on port login of 0x%06x@0x%0x", mbs.param[0], portid, handle); return (mbs.param[0]); } } +/* + * Pre-24XX fabric port logout + * + * Note that portid is not used + */ static int isp_port_logout(ispsoftc_t *isp, uint16_t handle, uint32_t portid) { mbreg_t mbs; MBSINIT(&mbs, MBOX_FABRIC_LOGOUT, MBLOGNONE, 500000); if (ISP_CAP_2KLOGIN(isp)) { mbs.param[1] = handle; mbs.ibits = (1 << 10); } else { mbs.param[1] = handle << 8; } isp_mboxcmd(isp, &mbs); return (mbs.param[0] == MBOX_COMMAND_COMPLETE? 0 : mbs.param[0]); } static int isp_getpdb(ispsoftc_t *isp, int chan, uint16_t id, isp_pdb_t *pdb, int dolock) { fcparam *fcp = FCPARAM(isp, chan); mbreg_t mbs; union { isp_pdb_21xx_t fred; isp_pdb_24xx_t bill; } un; MBSINIT(&mbs, MBOX_GET_PORT_DB, MBLOGALL & ~MBOX_COMMAND_PARAM_ERROR, 250000); if (IS_24XX(isp)) { mbs.ibits = (1 << 9)|(1 << 10); mbs.param[1] = id; mbs.param[9] = chan; } else if (ISP_CAP_2KLOGIN(isp)) { mbs.param[1] = id; } else { mbs.param[1] = id << 8; } mbs.param[2] = DMA_WD1(fcp->isp_scdma); mbs.param[3] = DMA_WD0(fcp->isp_scdma); mbs.param[6] = DMA_WD3(fcp->isp_scdma); mbs.param[7] = DMA_WD2(fcp->isp_scdma); if (dolock) { if (FC_SCRATCH_ACQUIRE(isp, chan)) { isp_prt(isp, ISP_LOGERR, sacq); return (-1); } } MEMORYBARRIER(isp, SYNC_SFORDEV, 0, sizeof (un), chan); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { if (dolock) { FC_SCRATCH_RELEASE(isp, chan); } return (mbs.param[0]); } if (IS_24XX(isp)) { isp_get_pdb_24xx(isp, fcp->isp_scratch, &un.bill); pdb->handle = un.bill.pdb_handle; pdb->s3_role = un.bill.pdb_prli_svc3; pdb->portid = BITS2WORD_24XX(un.bill.pdb_portid_bits); ISP_MEMCPY(pdb->portname, un.bill.pdb_portname, 8); ISP_MEMCPY(pdb->nodename, un.bill.pdb_nodename, 8); isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d Port 0x%06x flags 0x%x curstate %x", chan, pdb->portid, un.bill.pdb_flags, un.bill.pdb_curstate); if (un.bill.pdb_curstate < PDB2400_STATE_PLOGI_DONE || un.bill.pdb_curstate > PDB2400_STATE_LOGGED_IN) { mbs.param[0] = MBOX_NOT_LOGGED_IN; if (dolock) { FC_SCRATCH_RELEASE(isp, chan); } return (mbs.param[0]); } } else { isp_get_pdb_21xx(isp, fcp->isp_scratch, &un.fred); pdb->handle = un.fred.pdb_loopid; pdb->s3_role = un.fred.pdb_prli_svc3; pdb->portid = BITS2WORD(un.fred.pdb_portid_bits); ISP_MEMCPY(pdb->portname, un.fred.pdb_portname, 8); ISP_MEMCPY(pdb->nodename, un.fred.pdb_nodename, 8); } if (dolock) { FC_SCRATCH_RELEASE(isp, chan); } return (0); } static void isp_dump_chip_portdb(ispsoftc_t *isp, int chan, int dolock) { isp_pdb_t pdb; int lim, loopid; if (ISP_CAP_2KLOGIN(isp)) { lim = NPH_MAX_2K; } else { lim = NPH_MAX; } for (loopid = 0; loopid != lim; loopid++) { if (isp_getpdb(isp, chan, loopid, &pdb, dolock)) { continue; } isp_prt(isp, ISP_LOGSANCFG|ISP_LOGINFO, "Chan %d Loopid 0x%04x " "PortID 0x%06x WWPN 0x%02x%02x%02x%02x%02x%02x%02x%02x", chan, loopid, pdb.portid, pdb.portname[0], pdb.portname[1], pdb.portname[2], pdb.portname[3], pdb.portname[4], pdb.portname[5], pdb.portname[6], pdb.portname[7]); } } static uint64_t isp_get_wwn(ispsoftc_t *isp, int chan, int loopid, int nodename) { uint64_t wwn = INI_NONE; fcparam *fcp = FCPARAM(isp, chan); mbreg_t mbs; if (fcp->isp_fwstate < FW_READY || fcp->isp_loopstate < LOOP_PDB_RCVD) { return (wwn); } MBSINIT(&mbs, MBOX_GET_PORT_NAME, MBLOGALL & ~MBOX_COMMAND_PARAM_ERROR, 500000); if (ISP_CAP_2KLOGIN(isp)) { mbs.param[1] = loopid; mbs.ibits = (1 << 10); if (nodename) { mbs.param[10] = 1; } if (ISP_CAP_MULTI_ID(isp)) { mbs.ibits |= (1 << 9); mbs.param[9] = chan; } } else { mbs.param[1] = loopid << 8; if (nodename) { mbs.param[1] |= 1; } } isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return (wwn); } if (IS_24XX(isp)) { wwn = (((uint64_t)(mbs.param[2] >> 8)) << 56) | (((uint64_t)(mbs.param[2] & 0xff)) << 48) | (((uint64_t)(mbs.param[3] >> 8)) << 40) | (((uint64_t)(mbs.param[3] & 0xff)) << 32) | (((uint64_t)(mbs.param[6] >> 8)) << 24) | (((uint64_t)(mbs.param[6] & 0xff)) << 16) | (((uint64_t)(mbs.param[7] >> 8)) << 8) | (((uint64_t)(mbs.param[7] & 0xff))); } else { wwn = (((uint64_t)(mbs.param[2] & 0xff)) << 56) | (((uint64_t)(mbs.param[2] >> 8)) << 48) | (((uint64_t)(mbs.param[3] & 0xff)) << 40) | (((uint64_t)(mbs.param[3] >> 8)) << 32) | (((uint64_t)(mbs.param[6] & 0xff)) << 24) | (((uint64_t)(mbs.param[6] >> 8)) << 16) | (((uint64_t)(mbs.param[7] & 0xff)) << 8) | (((uint64_t)(mbs.param[7] >> 8))); } return (wwn); } /* * Make sure we have good FC link. */ static int isp_fclink_test(ispsoftc_t *isp, int chan, int usdelay) { mbreg_t mbs; int count, check_for_fabric, r; uint8_t lwfs; int loopid; fcparam *fcp; fcportdb_t *lp; isp_pdb_t pdb; fcp = FCPARAM(isp, chan); isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d FC Link Test Entry", chan); ISP_MARK_PORTDB(isp, chan, 1); /* * Wait up to N microseconds for F/W to go to a ready state. */ lwfs = FW_CONFIG_WAIT; count = 0; while (count < usdelay) { uint64_t enano; uint32_t wrk; NANOTIME_T hra, hrb; GET_NANOTIME(&hra); isp_fw_state(isp, chan); if (lwfs != fcp->isp_fwstate) { isp_prt(isp, ISP_LOGCONFIG|ISP_LOGSANCFG, "Chan %d Firmware State <%s->%s>", chan, isp_fc_fw_statename((int)lwfs), isp_fc_fw_statename((int)fcp->isp_fwstate)); lwfs = fcp->isp_fwstate; } if (fcp->isp_fwstate == FW_READY) { break; } GET_NANOTIME(&hrb); /* * Get the elapsed time in nanoseconds. * Always guaranteed to be non-zero. */ enano = NANOTIME_SUB(&hrb, &hra); isp_prt(isp, ISP_LOGDEBUG1, "usec%d: 0x%lx->0x%lx enano 0x%x%08x", count, (long) GET_NANOSEC(&hra), (long) GET_NANOSEC(&hrb), (uint32_t)(enano >> 32), (uint32_t)(enano)); /* * If the elapsed time is less than 1 millisecond, * delay a period of time up to that millisecond of * waiting. * * This peculiar code is an attempt to try and avoid * invoking uint64_t math support functions for some * platforms where linkage is a problem. */ if (enano < (1000 * 1000)) { count += 1000; enano = (1000 * 1000) - enano; while (enano > (uint64_t) 4000000000U) { ISP_SLEEP(isp, 4000000); enano -= (uint64_t) 4000000000U; } wrk = enano; wrk /= 1000; ISP_SLEEP(isp, wrk); } else { while (enano > (uint64_t) 4000000000U) { count += 4000000; enano -= (uint64_t) 4000000000U; } wrk = enano; count += (wrk / 1000); } } /* * If we haven't gone to 'ready' state, return. */ if (fcp->isp_fwstate != FW_READY) { isp_prt(isp, ISP_LOGSANCFG, "%s: chan %d not at FW_READY state", __func__, chan); return (-1); } /* * Get our Loop ID and Port ID. */ MBSINIT(&mbs, MBOX_GET_LOOP_ID, MBLOGALL, 0); if (ISP_CAP_MULTI_ID(isp)) { mbs.param[9] = chan; mbs.ibits = (1 << 9); mbs.obits = (1 << 7); } isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return (-1); } if (ISP_CAP_2KLOGIN(isp)) { fcp->isp_loopid = mbs.param[1]; } else { fcp->isp_loopid = mbs.param[1] & 0xff; } if (IS_2100(isp)) { fcp->isp_topo = TOPO_NL_PORT; } else { int topo = (int) mbs.param[6]; if (topo < TOPO_NL_PORT || topo > TOPO_PTP_STUB) { topo = TOPO_PTP_STUB; } fcp->isp_topo = topo; } fcp->isp_portid = mbs.param[2] | (mbs.param[3] << 16); if (IS_2100(isp)) { /* * Don't bother with fabric if we are using really old * 2100 firmware. It's just not worth it. */ if (ISP_FW_NEWER_THAN(isp, 1, 15, 37)) { check_for_fabric = 1; } else { check_for_fabric = 0; } } else if (fcp->isp_topo == TOPO_FL_PORT || fcp->isp_topo == TOPO_F_PORT) { check_for_fabric = 1; } else { check_for_fabric = 0; } /* * Check to make sure we got a valid loopid * The 24XX seems to mess this up for multiple channels. */ if (fcp->isp_topo == TOPO_FL_PORT || fcp->isp_topo == TOPO_NL_PORT) { uint8_t alpa = fcp->isp_portid; if (alpa == 0) { /* "Cannot Happen" */ isp_prt(isp, ISP_LOGWARN, "Zero AL_PA for Loop Topology?"); } else { int i; for (i = 0; alpa_map[i]; i++) { if (alpa_map[i] == alpa) { break; } } if (alpa_map[i] && fcp->isp_loopid != i) { isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d deriving loopid %d from AL_PA map (AL_PA 0x%x) and ignoring returned value %d (AL_PA 0x%x)", chan, i, alpa_map[i], fcp->isp_loopid, alpa); fcp->isp_loopid = i; } } } if (IS_24XX(isp)) { /* XXX SHOULDN'T THIS BE FOR 2K F/W? XXX */ loopid = NPH_FL_ID; } else { loopid = FL_ID; } if (check_for_fabric) { r = isp_getpdb(isp, chan, loopid, &pdb, 1); if (r && (fcp->isp_topo == TOPO_F_PORT || fcp->isp_topo == TOPO_FL_PORT)) { isp_prt(isp, ISP_LOGWARN, "fabric topology but cannot get info about fabric controller (0x%x)", r); fcp->isp_topo = TOPO_PTP_STUB; } } else { r = -1; } if (r == 0) { if (IS_2100(isp)) { fcp->isp_topo = TOPO_FL_PORT; } if (pdb.portid == 0) { /* * Crock. */ fcp->isp_topo = TOPO_NL_PORT; goto not_on_fabric; } /* * Save the Fabric controller's port database entry. */ lp = &fcp->portdb[FL_ID]; lp->state = FC_PORTDB_STATE_PENDING_VALID; MAKE_WWN_FROM_NODE_NAME(lp->node_wwn, pdb.nodename); MAKE_WWN_FROM_NODE_NAME(lp->port_wwn, pdb.portname); lp->roles = (pdb.s3_role & SVC3_ROLE_MASK) >> SVC3_ROLE_SHIFT; lp->portid = pdb.portid; lp->handle = pdb.handle; lp->new_portid = lp->portid; lp->new_roles = lp->roles; if (IS_24XX(isp)) { fcp->inorder = (mbs.param[7] & ISP24XX_INORDER) != 0; if (ISP_FW_NEWER_THAN(isp, 4, 0, 27)) { fcp->npiv_fabric = (mbs.param[7] & ISP24XX_NPIV_SAN) != 0; if (fcp->npiv_fabric) { isp_prt(isp, ISP_LOGCONFIG, "fabric supports NP-IV"); } } if (chan) { fcp->isp_sns_hdl = NPH_SNS_HDLBASE + chan; r = isp_plogx(isp, chan, fcp->isp_sns_hdl, SNS_PORT_ID, PLOGX_FLG_CMD_PLOGI | PLOGX_FLG_COND_PLOGI | PLOGX_FLG_SKIP_PRLI, 0); if (r) { isp_prt(isp, ISP_LOGWARN, "%s: Chan %d cannot log into SNS", __func__, chan); return (-1); } } else { fcp->isp_sns_hdl = NPH_SNS_ID; } r = isp_register_fc4_type_24xx(isp, chan); } else { fcp->isp_sns_hdl = SNS_ID; r = isp_register_fc4_type(isp, chan); } if (r) { isp_prt(isp, ISP_LOGWARN|ISP_LOGSANCFG, "%s: register fc4 type failed", __func__); return (-1); } } else { not_on_fabric: fcp->portdb[FL_ID].state = FC_PORTDB_STATE_NIL; } fcp->isp_gbspeed = 1; if (IS_23XX(isp) || IS_24XX(isp)) { MBSINIT(&mbs, MBOX_GET_SET_DATA_RATE, MBLOGALL, 3000000); mbs.param[1] = MBGSD_GET_RATE; /* mbs.param[2] undefined if we're just getting rate */ isp_mboxcmd(isp, &mbs); if (mbs.param[0] == MBOX_COMMAND_COMPLETE) { if (mbs.param[1] == MBGSD_EIGHTGB) { isp_prt(isp, ISP_LOGINFO, "Chan %d 8Gb link speed", chan); fcp->isp_gbspeed = 8; } else if (mbs.param[1] == MBGSD_FOURGB) { isp_prt(isp, ISP_LOGINFO, "Chan %d 4Gb link speed", chan); fcp->isp_gbspeed = 4; } else if (mbs.param[1] == MBGSD_TWOGB) { isp_prt(isp, ISP_LOGINFO, "Chan %d 2Gb link speed", chan); fcp->isp_gbspeed = 2; } else if (mbs.param[1] == MBGSD_ONEGB) { isp_prt(isp, ISP_LOGINFO, "Chan %d 1Gb link speed", chan); fcp->isp_gbspeed = 1; } } } /* * Announce ourselves, too. */ isp_prt(isp, ISP_LOGSANCFG|ISP_LOGCONFIG, topology, chan, (uint32_t) (fcp->isp_wwpn >> 32), (uint32_t) fcp->isp_wwpn, fcp->isp_portid, fcp->isp_loopid, isp_fc_toponame(fcp)); isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d FC Link Test Complete", chan); return (0); } /* * Complete the synchronization of our Port Database. * * At this point, we've scanned the local loop (if any) and the fabric * and performed fabric logins on all new devices. * * Our task here is to go through our port database and remove any entities * that are still marked probational (issuing PLOGO for ones which we had * PLOGI'd into) or are dead. * * Our task here is to also check policy to decide whether devices which * have *changed* in some way should still be kept active. For example, * if a device has just changed PortID, we can either elect to treat it * as an old device or as a newly arrived device (and notify the outer * layer appropriately). * * We also do initiator map target id assignment here for new initiator - * devices and refresh old ones ot make sure that they point to the corret + * devices and refresh old ones ot make sure that they point to the correct * entities. */ static int isp_pdb_sync(ispsoftc_t *isp, int chan) { fcparam *fcp = FCPARAM(isp, chan); fcportdb_t *lp; uint16_t dbidx; if (fcp->isp_loopstate == LOOP_READY) { return (0); } /* * Make sure we're okay for doing this right now. */ if (fcp->isp_loopstate != LOOP_PDB_RCVD && fcp->isp_loopstate != LOOP_FSCAN_DONE && fcp->isp_loopstate != LOOP_LSCAN_DONE) { isp_prt(isp, ISP_LOGWARN, "isp_pdb_sync: bad loopstate %d", fcp->isp_loopstate); return (-1); } if (fcp->isp_topo == TOPO_FL_PORT || fcp->isp_topo == TOPO_NL_PORT || fcp->isp_topo == TOPO_N_PORT) { if (fcp->isp_loopstate < LOOP_LSCAN_DONE) { if (isp_scan_loop(isp, chan) != 0) { isp_prt(isp, ISP_LOGWARN, "isp_pdb_sync: isp_scan_loop failed"); return (-1); } } } if (fcp->isp_topo == TOPO_F_PORT || fcp->isp_topo == TOPO_FL_PORT) { if (fcp->isp_loopstate < LOOP_FSCAN_DONE) { if (isp_scan_fabric(isp, chan) != 0) { isp_prt(isp, ISP_LOGWARN, "isp_pdb_sync: isp_scan_fabric failed"); return (-1); } } } isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d Synchronizing PDBs", chan); fcp->isp_loopstate = LOOP_SYNCING_PDB; for (dbidx = 0; dbidx < MAX_FC_TARG; dbidx++) { lp = &fcp->portdb[dbidx]; if (lp->state == FC_PORTDB_STATE_NIL || lp->target_mode) { continue; } if (lp->state == FC_PORTDB_STATE_VALID) { if (dbidx != FL_ID) { isp_prt(isp, ISP_LOGERR, "portdb idx %d already valid", dbidx); } continue; } switch (lp->state) { case FC_PORTDB_STATE_PROBATIONAL: case FC_PORTDB_STATE_DEAD: /* * It's up to the outer layers to clear isp_dev_map. */ lp->state = FC_PORTDB_STATE_NIL; isp_async(isp, ISPASYNC_DEV_GONE, chan, lp); if (lp->autologin == 0) { (void) isp_plogx(isp, chan, lp->handle, lp->portid, PLOGX_FLG_CMD_LOGO | PLOGX_FLG_IMPLICIT | PLOGX_FLG_FREE_NPHDL, 0); } else { lp->autologin = 0; } lp->new_roles = 0; lp->new_portid = 0; /* * Note that we might come out of this with our state * set to FC_PORTDB_STATE_ZOMBIE. */ break; case FC_PORTDB_STATE_NEW: /* * It's up to the outer layers to assign a virtual * target id in isp_dev_map (if any). */ lp->portid = lp->new_portid; lp->roles = lp->new_roles; lp->state = FC_PORTDB_STATE_VALID; isp_async(isp, ISPASYNC_DEV_ARRIVED, chan, lp); lp->new_roles = 0; lp->new_portid = 0; lp->reserved = 0; lp->new_reserved = 0; break; case FC_PORTDB_STATE_CHANGED: /* * XXXX FIX THIS */ lp->state = FC_PORTDB_STATE_VALID; isp_async(isp, ISPASYNC_DEV_CHANGED, chan, lp); lp->new_roles = 0; lp->new_portid = 0; lp->reserved = 0; lp->new_reserved = 0; break; case FC_PORTDB_STATE_PENDING_VALID: lp->portid = lp->new_portid; lp->roles = lp->new_roles; if (lp->dev_map_idx) { int t = lp->dev_map_idx - 1; fcp->isp_dev_map[t] = dbidx + 1; } lp->state = FC_PORTDB_STATE_VALID; isp_async(isp, ISPASYNC_DEV_STAYED, chan, lp); if (dbidx != FL_ID) { lp->new_roles = 0; lp->new_portid = 0; } lp->reserved = 0; lp->new_reserved = 0; break; case FC_PORTDB_STATE_ZOMBIE: break; default: isp_prt(isp, ISP_LOGWARN, "isp_scan_loop: state %d for idx %d", lp->state, dbidx); isp_dump_portdb(isp, chan); } } /* * If we get here, we've for sure seen not only a valid loop * but know what is or isn't on it, so mark this for usage * in isp_start. */ fcp->loop_seen_once = 1; fcp->isp_loopstate = LOOP_READY; return (0); } /* * Scan local loop for devices. */ static int isp_scan_loop(ispsoftc_t *isp, int chan) { fcportdb_t *lp, tmp; fcparam *fcp = FCPARAM(isp, chan); int i; isp_pdb_t pdb; uint16_t handle, lim = 0; if (fcp->isp_fwstate < FW_READY || fcp->isp_loopstate < LOOP_PDB_RCVD) { return (-1); } if (fcp->isp_loopstate > LOOP_SCANNING_LOOP) { return (0); } /* * Check our connection topology. * * If we're a public or private loop, we scan 0..125 as handle values. * The firmware has (typically) peformed a PLOGI for us. We skip this * step if we're a ISP_24XX in NP-IV mode. * * If we're a N-port connection, we treat this is a short loop (0..1). */ switch (fcp->isp_topo) { case TOPO_NL_PORT: lim = LOCAL_LOOP_LIM; break; case TOPO_FL_PORT: if (IS_24XX(isp) && isp->isp_nchan > 1) { isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d Skipping Local Loop Scan", chan); fcp->isp_loopstate = LOOP_LSCAN_DONE; return (0); } lim = LOCAL_LOOP_LIM; break; case TOPO_N_PORT: lim = 2; break; default: isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d no loop topology to scan", chan); fcp->isp_loopstate = LOOP_LSCAN_DONE; return (0); } fcp->isp_loopstate = LOOP_SCANNING_LOOP; isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d FC scan loop 0..%d", chan, lim-1); /* * Run through the list and get the port database info for each one. */ for (handle = 0; handle < lim; handle++) { int r; /* * Don't scan "special" ids. */ if (handle >= FL_ID && handle <= SNS_ID) { continue; } if (ISP_CAP_2KLOGIN(isp)) { if (handle >= NPH_RESERVED && handle <= NPH_FL_ID) { continue; } } /* * In older cards with older f/w GET_PORT_DATABASE has been * known to hang. This trick gets around that problem. */ if (IS_2100(isp) || IS_2200(isp)) { uint64_t node_wwn = isp_get_wwn(isp, chan, handle, 1); if (fcp->isp_loopstate < LOOP_SCANNING_LOOP) { isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d FC scan loop DONE (bad)", chan); return (-1); } if (node_wwn == INI_NONE) { continue; } } /* * Get the port database entity for this index. */ r = isp_getpdb(isp, chan, handle, &pdb, 1); if (r != 0) { isp_prt(isp, ISP_LOGDEBUG1, "Chan %d FC scan loop handle %d returned %x", chan, handle, r); if (fcp->isp_loopstate < LOOP_SCANNING_LOOP) { ISP_MARK_PORTDB(isp, chan, 1); isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d FC scan loop DONE (bad)", chan); return (-1); } continue; } if (fcp->isp_loopstate < LOOP_SCANNING_LOOP) { ISP_MARK_PORTDB(isp, chan, 1); isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d FC scan loop DONE (bad)", chan); return (-1); } /* * On *very* old 2100 firmware we would end up sometimes * with the firmware returning the port database entry * for something else. We used to restart this, but * now we just punt. */ if (IS_2100(isp) && pdb.handle != handle) { isp_prt(isp, ISP_LOGWARN, "Chan %d cannot synchronize port database", chan); ISP_MARK_PORTDB(isp, chan, 1); isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d FC scan loop DONE (bad)", chan); return (-1); } /* * Save the pertinent info locally. */ MAKE_WWN_FROM_NODE_NAME(tmp.node_wwn, pdb.nodename); MAKE_WWN_FROM_NODE_NAME(tmp.port_wwn, pdb.portname); tmp.roles = (pdb.s3_role & SVC3_ROLE_MASK) >> SVC3_ROLE_SHIFT; tmp.portid = pdb.portid; tmp.handle = pdb.handle; /* * Check to make sure it's still a valid entry. The 24XX seems * to return a portid but not a WWPN/WWNN or role for devices * which shift on a loop. */ if (tmp.node_wwn == 0 || tmp.port_wwn == 0 || tmp.portid == 0) { int a, b, c; a = (tmp.node_wwn == 0); b = (tmp.port_wwn == 0); c = (tmp.portid == 0); if (a == 0 && b == 0) { tmp.node_wwn = isp_get_wwn(isp, chan, handle, 1); tmp.port_wwn = isp_get_wwn(isp, chan, handle, 0); if (tmp.node_wwn && tmp.port_wwn) { isp_prt(isp, ISP_LOGINFO, "DODGED!"); goto cont; } } isp_prt(isp, ISP_LOGWARN, "Chan %d bad pdb (%1d%1d%1d) @ handle 0x%x", chan, a, b, c, handle); isp_dump_portdb(isp, chan); continue; } cont: /* * Now search the entire port database * for the same Port and Node WWN. */ for (i = 0; i < MAX_FC_TARG; i++) { lp = &fcp->portdb[i]; if (lp->state == FC_PORTDB_STATE_NIL || lp->target_mode) { continue; } if (lp->node_wwn != tmp.node_wwn) { continue; } if (lp->port_wwn != tmp.port_wwn) { continue; } /* * Okay- we've found a non-nil entry that matches. * Check to make sure it's probational or a zombie. */ if (lp->state != FC_PORTDB_STATE_PROBATIONAL && lp->state != FC_PORTDB_STATE_ZOMBIE) { isp_prt(isp, ISP_LOGERR, "Chan %d [%d] not probational/zombie (0x%x)", chan, i, lp->state); isp_dump_portdb(isp, chan); ISP_MARK_PORTDB(isp, chan, 1); isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d FC scan loop DONE (bad)", chan); return (-1); } /* * Mark the device as something the f/w logs into * automatically. */ lp->autologin = 1; /* * Check to make see if really still the same * device. If it is, we mark it pending valid. */ if (lp->portid == tmp.portid && lp->handle == tmp.handle && lp->roles == tmp.roles) { lp->new_portid = tmp.portid; lp->new_roles = tmp.roles; lp->state = FC_PORTDB_STATE_PENDING_VALID; isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d Loop Port 0x%06x@0x%04x Pending " "Valid", chan, tmp.portid, tmp.handle); break; } /* * We can wipe out the old handle value * here because it's no longer valid. */ lp->handle = tmp.handle; /* * Claim that this has changed and let somebody else * decide what to do. */ isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d Loop Port 0x%06x@0x%04x changed", chan, tmp.portid, tmp.handle); lp->state = FC_PORTDB_STATE_CHANGED; lp->new_portid = tmp.portid; lp->new_roles = tmp.roles; break; } /* * Did we find and update an old entry? */ if (i < MAX_FC_TARG) { continue; } /* * Ah. A new device entry. Find an empty slot * for it and save info for later disposition. */ for (i = 0; i < MAX_FC_TARG; i++) { if (fcp->portdb[i].target_mode) { continue; } if (fcp->portdb[i].state == FC_PORTDB_STATE_NIL) { break; } } if (i == MAX_FC_TARG) { isp_prt(isp, ISP_LOGERR, "Chan %d out of portdb entries", chan); continue; } lp = &fcp->portdb[i]; ISP_MEMZERO(lp, sizeof (fcportdb_t)); lp->autologin = 1; lp->state = FC_PORTDB_STATE_NEW; lp->new_portid = tmp.portid; lp->new_roles = tmp.roles; lp->handle = tmp.handle; lp->port_wwn = tmp.port_wwn; lp->node_wwn = tmp.node_wwn; isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d Loop Port 0x%06x@0x%04x is New Entry", chan, tmp.portid, tmp.handle); } fcp->isp_loopstate = LOOP_LSCAN_DONE; isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d FC scan loop DONE", chan); return (0); } /* * Scan the fabric for devices and add them to our port database. * * Use the GID_FT command to get all Port IDs for FC4 SCSI devices it knows. * * For 2100-23XX cards, we can use the SNS mailbox command to pass simple * name server commands to the switch management server via the QLogic f/w. * * For the 24XX card, we have to use CT-Pass through run via the Execute IOCB * mailbox command. * * The net result is to leave the list of Port IDs setting untranslated in * offset IGPOFF of the FC scratch area, whereupon we'll canonicalize it to * host order at OGPOFF. */ /* * Take less than half of our scratch area to store Port IDs */ #define GIDLEN ((ISP_FC_SCRLEN >> 1) - 16 - SNS_GID_FT_REQ_SIZE) #define NGENT ((GIDLEN - 16) >> 2) #define IGPOFF (2 * QENTRY_LEN) #define OGPOFF (ISP_FC_SCRLEN >> 1) #define ZTXOFF (ISP_FC_SCRLEN - (1 * QENTRY_LEN)) #define CTXOFF (ISP_FC_SCRLEN - (2 * QENTRY_LEN)) #define XTXOFF (ISP_FC_SCRLEN - (3 * QENTRY_LEN)) static int isp_gid_ft_sns(ispsoftc_t *isp, int chan) { union { sns_gid_ft_req_t _x; uint8_t _y[SNS_GID_FT_REQ_SIZE]; } un; fcparam *fcp = FCPARAM(isp, chan); sns_gid_ft_req_t *rq = &un._x; mbreg_t mbs; isp_prt(isp, ISP_LOGDEBUG0, "Chan %d scanning fabric (GID_FT) via SNS", chan); ISP_MEMZERO(rq, SNS_GID_FT_REQ_SIZE); rq->snscb_rblen = GIDLEN >> 1; rq->snscb_addr[RQRSP_ADDR0015] = DMA_WD0(fcp->isp_scdma + IGPOFF); rq->snscb_addr[RQRSP_ADDR1631] = DMA_WD1(fcp->isp_scdma + IGPOFF); rq->snscb_addr[RQRSP_ADDR3247] = DMA_WD2(fcp->isp_scdma + IGPOFF); rq->snscb_addr[RQRSP_ADDR4863] = DMA_WD3(fcp->isp_scdma + IGPOFF); rq->snscb_sblen = 6; rq->snscb_cmd = SNS_GID_FT; rq->snscb_mword_div_2 = NGENT; rq->snscb_fc4_type = FC4_SCSI; isp_put_gid_ft_request(isp, rq, fcp->isp_scratch); MEMORYBARRIER(isp, SYNC_SFORDEV, 0, SNS_GID_FT_REQ_SIZE, chan); MBSINIT(&mbs, MBOX_SEND_SNS, MBLOGALL, 10000000); mbs.param[0] = MBOX_SEND_SNS; mbs.param[1] = SNS_GID_FT_REQ_SIZE >> 1; mbs.param[2] = DMA_WD1(fcp->isp_scdma); mbs.param[3] = DMA_WD0(fcp->isp_scdma); mbs.param[6] = DMA_WD3(fcp->isp_scdma); mbs.param[7] = DMA_WD2(fcp->isp_scdma); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { if (mbs.param[0] == MBOX_INVALID_COMMAND) { return (1); } else { return (-1); } } return (0); } static int isp_gid_ft_ct_passthru(ispsoftc_t *isp, int chan) { mbreg_t mbs; fcparam *fcp = FCPARAM(isp, chan); union { isp_ct_pt_t plocal; ct_hdr_t clocal; uint8_t q[QENTRY_LEN]; } un; isp_ct_pt_t *pt; ct_hdr_t *ct; uint32_t *rp; uint8_t *scp = fcp->isp_scratch; isp_prt(isp, ISP_LOGDEBUG0, "Chan %d scanning fabric (GID_FT) via CT", chan); if (!IS_24XX(isp)) { return (1); } /* * Build a Passthrough IOCB in memory. */ pt = &un.plocal; ISP_MEMZERO(un.q, QENTRY_LEN); pt->ctp_header.rqs_entry_count = 1; pt->ctp_header.rqs_entry_type = RQSTYPE_CT_PASSTHRU; pt->ctp_handle = 0xffffffff; pt->ctp_nphdl = fcp->isp_sns_hdl; pt->ctp_cmd_cnt = 1; pt->ctp_vpidx = ISP_GET_VPIDX(isp, chan); pt->ctp_time = 30; pt->ctp_rsp_cnt = 1; pt->ctp_rsp_bcnt = GIDLEN; pt->ctp_cmd_bcnt = sizeof (*ct) + sizeof (uint32_t); pt->ctp_dataseg[0].ds_base = DMA_LO32(fcp->isp_scdma+XTXOFF); pt->ctp_dataseg[0].ds_basehi = DMA_HI32(fcp->isp_scdma+XTXOFF); pt->ctp_dataseg[0].ds_count = sizeof (*ct) + sizeof (uint32_t); pt->ctp_dataseg[1].ds_base = DMA_LO32(fcp->isp_scdma+IGPOFF); pt->ctp_dataseg[1].ds_basehi = DMA_HI32(fcp->isp_scdma+IGPOFF); pt->ctp_dataseg[1].ds_count = GIDLEN; if (isp->isp_dblev & ISP_LOGDEBUG1) { isp_print_bytes(isp, "ct IOCB", QENTRY_LEN, pt); } isp_put_ct_pt(isp, pt, (isp_ct_pt_t *) &scp[CTXOFF]); /* * Build the CT header and command in memory. * * Note that the CT header has to end up as Big Endian format in memory. */ ct = &un.clocal; ISP_MEMZERO(ct, sizeof (*ct)); ct->ct_revision = CT_REVISION; ct->ct_fcs_type = CT_FC_TYPE_FC; ct->ct_fcs_subtype = CT_FC_SUBTYPE_NS; ct->ct_cmd_resp = SNS_GID_FT; ct->ct_bcnt_resid = (GIDLEN - 16) >> 2; isp_put_ct_hdr(isp, ct, (ct_hdr_t *) &scp[XTXOFF]); rp = (uint32_t *) &scp[XTXOFF+sizeof (*ct)]; ISP_IOZPUT_32(isp, FC4_SCSI, rp); if (isp->isp_dblev & ISP_LOGDEBUG1) { isp_print_bytes(isp, "CT HDR + payload after put", sizeof (*ct) + sizeof (uint32_t), &scp[XTXOFF]); } ISP_MEMZERO(&scp[ZTXOFF], QENTRY_LEN); MBSINIT(&mbs, MBOX_EXEC_COMMAND_IOCB_A64, MBLOGALL, 500000); mbs.param[1] = QENTRY_LEN; mbs.param[2] = DMA_WD1(fcp->isp_scdma + CTXOFF); mbs.param[3] = DMA_WD0(fcp->isp_scdma + CTXOFF); mbs.param[6] = DMA_WD3(fcp->isp_scdma + CTXOFF); mbs.param[7] = DMA_WD2(fcp->isp_scdma + CTXOFF); MEMORYBARRIER(isp, SYNC_SFORDEV, XTXOFF, 2 * QENTRY_LEN, chan); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { return (-1); } MEMORYBARRIER(isp, SYNC_SFORCPU, ZTXOFF, QENTRY_LEN, chan); pt = &un.plocal; isp_get_ct_pt(isp, (isp_ct_pt_t *) &scp[ZTXOFF], pt); if (isp->isp_dblev & ISP_LOGDEBUG1) { isp_print_bytes(isp, "IOCB response", QENTRY_LEN, pt); } if (pt->ctp_status && pt->ctp_status != RQCS_DATA_UNDERRUN) { isp_prt(isp, ISP_LOGWARN, "Chan %d ISP GID FT CT Passthrough returned 0x%x", chan, pt->ctp_status); return (-1); } MEMORYBARRIER(isp, SYNC_SFORCPU, IGPOFF, GIDLEN + 16, chan); if (isp->isp_dblev & ISP_LOGDEBUG1) { isp_print_bytes(isp, "CT response", GIDLEN+16, &scp[IGPOFF]); } return (0); } static int isp_scan_fabric(ispsoftc_t *isp, int chan) { fcparam *fcp = FCPARAM(isp, chan); uint32_t portid; uint16_t handle, oldhandle, loopid; isp_pdb_t pdb; int portidx, portlim, r; sns_gid_ft_rsp_t *rs0, *rs1; isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d FC Scan Fabric", chan); if (fcp->isp_fwstate != FW_READY || fcp->isp_loopstate < LOOP_LSCAN_DONE) { return (-1); } if (fcp->isp_loopstate > LOOP_SCANNING_FABRIC) { return (0); } if (fcp->isp_topo != TOPO_FL_PORT && fcp->isp_topo != TOPO_F_PORT) { fcp->isp_loopstate = LOOP_FSCAN_DONE; isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d FC Scan Fabric Done (no fabric)", chan); return (0); } fcp->isp_loopstate = LOOP_SCANNING_FABRIC; if (FC_SCRATCH_ACQUIRE(isp, chan)) { isp_prt(isp, ISP_LOGERR, sacq); ISP_MARK_PORTDB(isp, chan, 1); return (-1); } if (fcp->isp_loopstate < LOOP_SCANNING_FABRIC) { FC_SCRATCH_RELEASE(isp, chan); ISP_MARK_PORTDB(isp, chan, 1); return (-1); } /* * Make sure we still are logged into the fabric controller. */ if (IS_24XX(isp)) { /* XXX SHOULDN'T THIS BE TRUE FOR 2K F/W? XXX */ loopid = NPH_FL_ID; } else { loopid = FL_ID; } r = isp_getpdb(isp, chan, loopid, &pdb, 0); if (r == MBOX_NOT_LOGGED_IN) { isp_dump_chip_portdb(isp, chan, 0); } if (r) { fcp->isp_loopstate = LOOP_PDB_RCVD; FC_SCRATCH_RELEASE(isp, chan); ISP_MARK_PORTDB(isp, chan, 1); return (-1); } if (IS_24XX(isp)) { r = isp_gid_ft_ct_passthru(isp, chan); } else { r = isp_gid_ft_sns(isp, chan); } if (fcp->isp_loopstate < LOOP_SCANNING_FABRIC) { FC_SCRATCH_RELEASE(isp, chan); ISP_MARK_PORTDB(isp, chan, 1); return (-1); } if (r > 0) { fcp->isp_loopstate = LOOP_FSCAN_DONE; FC_SCRATCH_RELEASE(isp, chan); return (0); } else if (r < 0) { fcp->isp_loopstate = LOOP_PDB_RCVD; /* try again */ FC_SCRATCH_RELEASE(isp, chan); return (0); } MEMORYBARRIER(isp, SYNC_SFORCPU, IGPOFF, GIDLEN, chan); rs0 = (sns_gid_ft_rsp_t *) ((uint8_t *)fcp->isp_scratch+IGPOFF); rs1 = (sns_gid_ft_rsp_t *) ((uint8_t *)fcp->isp_scratch+OGPOFF); isp_get_gid_ft_response(isp, rs0, rs1, NGENT); if (fcp->isp_loopstate < LOOP_SCANNING_FABRIC) { FC_SCRATCH_RELEASE(isp, chan); ISP_MARK_PORTDB(isp, chan, 1); return (-1); } if (rs1->snscb_cthdr.ct_cmd_resp != LS_ACC) { int level; if (rs1->snscb_cthdr.ct_reason == 9 && rs1->snscb_cthdr.ct_explanation == 7) { level = ISP_LOGSANCFG|ISP_LOGDEBUG0; } else { level = ISP_LOGWARN; } isp_prt(isp, level, "Chan %d Fabric Nameserver rejected GID_FT" " (Reason=0x%x Expl=0x%x)", chan, rs1->snscb_cthdr.ct_reason, rs1->snscb_cthdr.ct_explanation); FC_SCRATCH_RELEASE(isp, chan); fcp->isp_loopstate = LOOP_FSCAN_DONE; return (0); } /* * If we get this far, we certainly still have the fabric controller. */ fcp->portdb[FL_ID].state = FC_PORTDB_STATE_PENDING_VALID; /* * Prime the handle we will start using. */ oldhandle = FCPARAM(isp, 0)->isp_lasthdl; /* * Go through the list and remove duplicate port ids. */ portlim = 0; portidx = 0; for (portidx = 0; portidx < NGENT-1; portidx++) { if (rs1->snscb_ports[portidx].control & 0x80) { break; } } /* * If we're not at the last entry, our list wasn't big enough. */ if ((rs1->snscb_ports[portidx].control & 0x80) == 0) { isp_prt(isp, ISP_LOGWARN, "fabric too big for scratch area: increase ISP_FC_SCRLEN"); } portlim = portidx + 1; isp_prt(isp, ISP_LOGSANCFG, "Chan %d got %d ports back from name server", chan, portlim); for (portidx = 0; portidx < portlim; portidx++) { int npidx; portid = ((rs1->snscb_ports[portidx].portid[0]) << 16) | ((rs1->snscb_ports[portidx].portid[1]) << 8) | ((rs1->snscb_ports[portidx].portid[2])); for (npidx = portidx + 1; npidx < portlim; npidx++) { uint32_t new_portid = ((rs1->snscb_ports[npidx].portid[0]) << 16) | ((rs1->snscb_ports[npidx].portid[1]) << 8) | ((rs1->snscb_ports[npidx].portid[2])); if (new_portid == portid) { break; } } if (npidx < portlim) { rs1->snscb_ports[npidx].portid[0] = 0; rs1->snscb_ports[npidx].portid[1] = 0; rs1->snscb_ports[npidx].portid[2] = 0; isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d removing duplicate PortID 0x%06x" " entry from list", chan, portid); } } /* * We now have a list of Port IDs for all FC4 SCSI devices * that the Fabric Name server knows about. * * For each entry on this list go through our port database looking * for probational entries- if we find one, then an old entry is * maybe still this one. We get some information to find out. * * Otherwise, it's a new fabric device, and we log into it * (unconditionally). After searching the entire database * again to make sure that we never ever ever ever have more * than one entry that has the same PortID or the same * WWNN/WWPN duple, we enter the device into our database. */ for (portidx = 0; portidx < portlim; portidx++) { fcportdb_t *lp; uint64_t wwnn, wwpn; int dbidx, nr; portid = ((rs1->snscb_ports[portidx].portid[0]) << 16) | ((rs1->snscb_ports[portidx].portid[1]) << 8) | ((rs1->snscb_ports[portidx].portid[2])); if (portid == 0) { isp_prt(isp, ISP_LOGSANCFG, "Chan %d skipping null PortID at idx %d", chan, portidx); continue; } /* * Skip ourselves here and on other channels. If we're * multi-id, we can't check the portids in other FCPARAM * arenas because the resolutions here aren't synchronized. * The best way to do this is to exclude looking at portids * that have the same domain and area code as our own * portid. */ if (ISP_CAP_MULTI_ID(isp)) { if ((portid >> 8) == (fcp->isp_portid >> 8)) { isp_prt(isp, ISP_LOGSANCFG, "Chan %d skip PortID 0x%06x", chan, portid); continue; } } else if (portid == fcp->isp_portid) { isp_prt(isp, ISP_LOGSANCFG, "Chan %d skip ourselves on @ PortID 0x%06x", chan, portid); continue; } isp_prt(isp, ISP_LOGSANCFG, "Chan %d Checking Fabric Port 0x%06x", chan, portid); /* * We now search our Port Database for any * probational entries with this PortID. We don't * look for zombies here- only probational * entries (we've already logged out of zombies). */ for (dbidx = 0; dbidx < MAX_FC_TARG; dbidx++) { lp = &fcp->portdb[dbidx]; if (lp->state != FC_PORTDB_STATE_PROBATIONAL || lp->target_mode) { continue; } if (lp->portid == portid) { break; } } /* * We found a probational entry with this Port ID. */ if (dbidx < MAX_FC_TARG) { int handle_changed = 0; lp = &fcp->portdb[dbidx]; /* * See if we're still logged into it. * * If we aren't, mark it as a dead device and * leave the new portid in the database entry * for somebody further along to decide what to * do (policy choice). * * If we are, check to see if it's the same * device still (it should be). If for some * reason it isn't, mark it as a changed device * and leave the new portid and role in the * database entry for somebody further along to * decide what to do (policy choice). * */ r = isp_getpdb(isp, chan, lp->handle, &pdb, 0); if (fcp->isp_loopstate != LOOP_SCANNING_FABRIC) { FC_SCRATCH_RELEASE(isp, chan); ISP_MARK_PORTDB(isp, chan, 1); return (-1); } if (r != 0) { lp->new_portid = portid; lp->state = FC_PORTDB_STATE_DEAD; isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d Fabric Port 0x%06x is dead", chan, portid); continue; } /* * Check to make sure that handle, portid, WWPN and * WWNN agree. If they don't, then the association * between this PortID and the stated handle has been * broken by the firmware. */ MAKE_WWN_FROM_NODE_NAME(wwnn, pdb.nodename); MAKE_WWN_FROM_NODE_NAME(wwpn, pdb.portname); if (pdb.handle != lp->handle || pdb.portid != portid || wwpn != lp->port_wwn || wwnn != lp->node_wwn) { isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, fconf, chan, dbidx, pdb.handle, pdb.portid, (uint32_t) (wwnn >> 32), (uint32_t) wwnn, (uint32_t) (wwpn >> 32), (uint32_t) wwpn, lp->handle, portid, (uint32_t) (lp->node_wwn >> 32), (uint32_t) lp->node_wwn, (uint32_t) (lp->port_wwn >> 32), (uint32_t) lp->port_wwn); /* * Try to re-login to this device using a * new handle. If that fails, mark it dead. * * isp_login_device will check for handle and * portid consistency after re-login. * */ if (isp_login_device(isp, chan, portid, &pdb, &oldhandle)) { lp->new_portid = portid; lp->state = FC_PORTDB_STATE_DEAD; if (fcp->isp_loopstate != LOOP_SCANNING_FABRIC) { FC_SCRATCH_RELEASE(isp, chan); ISP_MARK_PORTDB(isp, chan, 1); return (-1); } continue; } if (fcp->isp_loopstate != LOOP_SCANNING_FABRIC) { FC_SCRATCH_RELEASE(isp, chan); ISP_MARK_PORTDB(isp, chan, 1); return (-1); } FCPARAM(isp, 0)->isp_lasthdl = oldhandle; MAKE_WWN_FROM_NODE_NAME(wwnn, pdb.nodename); MAKE_WWN_FROM_NODE_NAME(wwpn, pdb.portname); if (wwpn != lp->port_wwn || wwnn != lp->node_wwn) { isp_prt(isp, ISP_LOGWARN, "changed WWN" " after relogin"); lp->new_portid = portid; lp->state = FC_PORTDB_STATE_DEAD; continue; } lp->handle = pdb.handle; handle_changed++; } nr = (pdb.s3_role & SVC3_ROLE_MASK) >> SVC3_ROLE_SHIFT; /* * Check to see whether the portid and roles have * stayed the same. If they have stayed the same, * we believe that this is the same device and it * hasn't become disconnected and reconnected, so * mark it as pending valid. * * If they aren't the same, mark the device as a * changed device and save the new port id and role * and let somebody else decide. */ lp->new_portid = portid; lp->new_roles = nr; if (pdb.portid != lp->portid || nr != lp->roles || handle_changed) { isp_prt(isp, ISP_LOGSANCFG, "Chan %d Fabric Port 0x%06x changed", chan, portid); lp->state = FC_PORTDB_STATE_CHANGED; } else { isp_prt(isp, ISP_LOGSANCFG, "Chan %d Fabric Port 0x%06x " "Now Pending Valid", chan, portid); lp->state = FC_PORTDB_STATE_PENDING_VALID; } continue; } /* * Ah- a new entry. Search the database again for all non-NIL * entries to make sure we never ever make a new database entry * with the same port id. While we're at it, mark where the * last free entry was. */ dbidx = MAX_FC_TARG; for (lp = fcp->portdb; lp < &fcp->portdb[MAX_FC_TARG]; lp++) { if (lp >= &fcp->portdb[FL_ID] && lp <= &fcp->portdb[SNS_ID]) { continue; } /* * Skip any target mode entries. */ if (lp->target_mode) { continue; } if (lp->state == FC_PORTDB_STATE_NIL) { if (dbidx == MAX_FC_TARG) { dbidx = lp - fcp->portdb; } continue; } if (lp->state == FC_PORTDB_STATE_ZOMBIE) { continue; } if (lp->portid == portid) { break; } } if (lp < &fcp->portdb[MAX_FC_TARG]) { isp_prt(isp, ISP_LOGWARN, "Chan %d PortID 0x%06x " "already at %d handle %d state %d", chan, portid, dbidx, lp->handle, lp->state); continue; } /* * We should have the index of the first free entry seen. */ if (dbidx == MAX_FC_TARG) { isp_prt(isp, ISP_LOGERR, "port database too small to login PortID 0x%06x" "- increase MAX_FC_TARG", portid); continue; } /* * Otherwise, point to our new home. */ lp = &fcp->portdb[dbidx]; /* * Try to see if we are logged into this device, * and maybe log into it. * * isp_login_device will check for handle and * portid consistency after login. */ if (isp_login_device(isp, chan, portid, &pdb, &oldhandle)) { if (fcp->isp_loopstate != LOOP_SCANNING_FABRIC) { FC_SCRATCH_RELEASE(isp, chan); ISP_MARK_PORTDB(isp, chan, 1); return (-1); } continue; } if (fcp->isp_loopstate != LOOP_SCANNING_FABRIC) { FC_SCRATCH_RELEASE(isp, chan); ISP_MARK_PORTDB(isp, chan, 1); return (-1); } FCPARAM(isp, 0)->isp_lasthdl = oldhandle; handle = pdb.handle; MAKE_WWN_FROM_NODE_NAME(wwnn, pdb.nodename); MAKE_WWN_FROM_NODE_NAME(wwpn, pdb.portname); nr = (pdb.s3_role & SVC3_ROLE_MASK) >> SVC3_ROLE_SHIFT; /* * And go through the database *one* more time to make sure * that we do not make more than one entry that has the same * WWNN/WWPN duple */ for (dbidx = 0; dbidx < MAX_FC_TARG; dbidx++) { if (dbidx >= FL_ID && dbidx <= SNS_ID) { continue; } if (fcp->portdb[dbidx].target_mode) { continue; } if (fcp->portdb[dbidx].node_wwn == wwnn && fcp->portdb[dbidx].port_wwn == wwpn) { break; } } if (dbidx == MAX_FC_TARG) { ISP_MEMZERO(lp, sizeof (fcportdb_t)); lp->handle = handle; lp->node_wwn = wwnn; lp->port_wwn = wwpn; lp->new_portid = portid; lp->new_roles = nr; lp->state = FC_PORTDB_STATE_NEW; isp_prt(isp, ISP_LOGSANCFG, "Chan %d Fabric Port 0x%06x is a New Entry", chan, portid); continue; } if (fcp->portdb[dbidx].state != FC_PORTDB_STATE_ZOMBIE) { isp_prt(isp, ISP_LOGWARN, "Chan %d PortID 0x%x 0x%08x%08x/0x%08x%08x %ld " "already at idx %d, state 0x%x", chan, portid, (uint32_t) (wwnn >> 32), (uint32_t) wwnn, (uint32_t) (wwpn >> 32), (uint32_t) wwpn, (long) (lp - fcp->portdb), dbidx, fcp->portdb[dbidx].state); continue; } /* * We found a zombie entry that matches us. * Revive it. We know that WWN and WWPN * are the same. For fabric devices, we * don't care that handle is different * as we assign that. If role or portid * are different, it maybe a changed device. */ lp = &fcp->portdb[dbidx]; lp->handle = handle; lp->new_portid = portid; lp->new_roles = nr; if (lp->portid != portid || lp->roles != nr) { isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d Zombie Fabric Port 0x%06x Now Changed", chan, portid); lp->state = FC_PORTDB_STATE_CHANGED; } else { isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d Zombie Fabric Port 0x%06x " "Now Pending Valid", chan, portid); lp->state = FC_PORTDB_STATE_PENDING_VALID; } } FC_SCRATCH_RELEASE(isp, chan); if (fcp->isp_loopstate != LOOP_SCANNING_FABRIC) { ISP_MARK_PORTDB(isp, chan, 1); return (-1); } fcp->isp_loopstate = LOOP_FSCAN_DONE; isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d FC Scan Fabric Done", chan); return (0); } /* * Find an unused handle and try and use to login to a port. */ static int isp_login_device(ispsoftc_t *isp, int chan, uint32_t portid, isp_pdb_t *p, uint16_t *ohp) { int lim, i, r; uint16_t handle; if (ISP_CAP_2KLOGIN(isp)) { lim = NPH_MAX_2K; } else { lim = NPH_MAX; } handle = isp_nxt_handle(isp, chan, *ohp); for (i = 0; i < lim; i++) { /* * See if we're still logged into something with * this handle and that something agrees with this * port id. */ r = isp_getpdb(isp, chan, handle, p, 0); if (r == 0 && p->portid != portid) { (void) isp_plogx(isp, chan, handle, portid, PLOGX_FLG_CMD_LOGO | PLOGX_FLG_IMPLICIT | PLOGX_FLG_FREE_NPHDL, 1); } else if (r == 0) { break; } if (FCPARAM(isp, chan)->isp_loopstate != LOOP_SCANNING_FABRIC) { return (-1); } /* * Now try and log into the device */ r = isp_plogx(isp, chan, handle, portid, PLOGX_FLG_CMD_PLOGI, 1); if (FCPARAM(isp, chan)->isp_loopstate != LOOP_SCANNING_FABRIC) { return (-1); } if (r == 0) { *ohp = handle; break; } else if ((r & 0xffff) == MBOX_PORT_ID_USED) { /* * If we get here, then the firmwware still thinks we're logged into this device, but with a different * handle. We need to break that association. We used to try and just substitute the handle, but then * failed to get any data via isp_getpdb (below). */ if (isp_plogx(isp, chan, r >> 16, portid, PLOGX_FLG_CMD_LOGO | PLOGX_FLG_IMPLICIT | PLOGX_FLG_FREE_NPHDL, 1)) { isp_prt(isp, ISP_LOGERR, "baw... logout of %x failed", r >> 16); } if (FCPARAM(isp, chan)->isp_loopstate != LOOP_SCANNING_FABRIC) { return (-1); } r = isp_plogx(isp, chan, handle, portid, PLOGX_FLG_CMD_PLOGI, 1); if (FCPARAM(isp, chan)->isp_loopstate != LOOP_SCANNING_FABRIC) { return (-1); } if (r == 0) { *ohp = handle; } else { i = lim; } break; } else if ((r & 0xffff) == MBOX_LOOP_ID_USED) { /* * Try the next loop id. */ *ohp = handle; handle = isp_nxt_handle(isp, chan, handle); } else { /* * Give up. */ i = lim; break; } } if (i == lim) { isp_prt(isp, ISP_LOGWARN, "Chan %d PLOGI 0x%06x failed", chan, portid); return (-1); } /* * If we successfully logged into it, get the PDB for it * so we can crosscheck that it is still what we think it * is and that we also have the role it plays */ r = isp_getpdb(isp, chan, handle, p, 0); if (FCPARAM(isp, chan)->isp_loopstate != LOOP_SCANNING_FABRIC) { return (-1); } if (r != 0) { isp_prt(isp, ISP_LOGERR, "Chan %d new device 0x%06x@0x%x disappeared", chan, portid, handle); return (-1); } if (p->handle != handle || p->portid != portid) { isp_prt(isp, ISP_LOGERR, "Chan %d new device 0x%06x@0x%x changed (0x%06x@0x%0x)", chan, portid, handle, p->portid, p->handle); return (-1); } return (0); } static int isp_register_fc4_type(ispsoftc_t *isp, int chan) { fcparam *fcp = FCPARAM(isp, chan); uint8_t local[SNS_RFT_ID_REQ_SIZE]; sns_screq_t *reqp = (sns_screq_t *) local; mbreg_t mbs; ISP_MEMZERO((void *) reqp, SNS_RFT_ID_REQ_SIZE); reqp->snscb_rblen = SNS_RFT_ID_RESP_SIZE >> 1; reqp->snscb_addr[RQRSP_ADDR0015] = DMA_WD0(fcp->isp_scdma + 0x100); reqp->snscb_addr[RQRSP_ADDR1631] = DMA_WD1(fcp->isp_scdma + 0x100); reqp->snscb_addr[RQRSP_ADDR3247] = DMA_WD2(fcp->isp_scdma + 0x100); reqp->snscb_addr[RQRSP_ADDR4863] = DMA_WD3(fcp->isp_scdma + 0x100); reqp->snscb_sblen = 22; reqp->snscb_data[0] = SNS_RFT_ID; reqp->snscb_data[4] = fcp->isp_portid & 0xffff; reqp->snscb_data[5] = (fcp->isp_portid >> 16) & 0xff; reqp->snscb_data[6] = (1 << FC4_SCSI); if (FC_SCRATCH_ACQUIRE(isp, chan)) { isp_prt(isp, ISP_LOGERR, sacq); return (-1); } isp_put_sns_request(isp, reqp, (sns_screq_t *) fcp->isp_scratch); MBSINIT(&mbs, MBOX_SEND_SNS, MBLOGALL, 1000000); mbs.param[1] = SNS_RFT_ID_REQ_SIZE >> 1; mbs.param[2] = DMA_WD1(fcp->isp_scdma); mbs.param[3] = DMA_WD0(fcp->isp_scdma); mbs.param[6] = DMA_WD3(fcp->isp_scdma); mbs.param[7] = DMA_WD2(fcp->isp_scdma); MEMORYBARRIER(isp, SYNC_SFORDEV, 0, SNS_RFT_ID_REQ_SIZE, chan); isp_mboxcmd(isp, &mbs); FC_SCRATCH_RELEASE(isp, chan); if (mbs.param[0] == MBOX_COMMAND_COMPLETE) { return (0); } else { return (-1); } } static int isp_register_fc4_type_24xx(ispsoftc_t *isp, int chan) { mbreg_t mbs; fcparam *fcp = FCPARAM(isp, chan); union { isp_ct_pt_t plocal; rft_id_t clocal; uint8_t q[QENTRY_LEN]; } un; isp_ct_pt_t *pt; ct_hdr_t *ct; rft_id_t *rp; uint8_t *scp = fcp->isp_scratch; if (FC_SCRATCH_ACQUIRE(isp, chan)) { isp_prt(isp, ISP_LOGERR, sacq); return (-1); } /* * Build a Passthrough IOCB in memory. */ ISP_MEMZERO(un.q, QENTRY_LEN); pt = &un.plocal; pt->ctp_header.rqs_entry_count = 1; pt->ctp_header.rqs_entry_type = RQSTYPE_CT_PASSTHRU; pt->ctp_handle = 0xffffffff; pt->ctp_nphdl = fcp->isp_sns_hdl; pt->ctp_cmd_cnt = 1; pt->ctp_vpidx = ISP_GET_VPIDX(isp, chan); pt->ctp_time = 1; pt->ctp_rsp_cnt = 1; pt->ctp_rsp_bcnt = sizeof (ct_hdr_t); pt->ctp_cmd_bcnt = sizeof (rft_id_t); pt->ctp_dataseg[0].ds_base = DMA_LO32(fcp->isp_scdma+XTXOFF); pt->ctp_dataseg[0].ds_basehi = DMA_HI32(fcp->isp_scdma+XTXOFF); pt->ctp_dataseg[0].ds_count = sizeof (rft_id_t); pt->ctp_dataseg[1].ds_base = DMA_LO32(fcp->isp_scdma+IGPOFF); pt->ctp_dataseg[1].ds_basehi = DMA_HI32(fcp->isp_scdma+IGPOFF); pt->ctp_dataseg[1].ds_count = sizeof (ct_hdr_t); isp_put_ct_pt(isp, pt, (isp_ct_pt_t *) &scp[CTXOFF]); if (isp->isp_dblev & ISP_LOGDEBUG1) { isp_print_bytes(isp, "IOCB CT Request", QENTRY_LEN, pt); } /* * Build the CT header and command in memory. * * Note that the CT header has to end up as Big Endian format in memory. */ ISP_MEMZERO(&un.clocal, sizeof (un.clocal)); ct = &un.clocal.rftid_hdr; ct->ct_revision = CT_REVISION; ct->ct_fcs_type = CT_FC_TYPE_FC; ct->ct_fcs_subtype = CT_FC_SUBTYPE_NS; ct->ct_cmd_resp = SNS_RFT_ID; ct->ct_bcnt_resid = (sizeof (rft_id_t) - sizeof (ct_hdr_t)) >> 2; rp = &un.clocal; rp->rftid_portid[0] = fcp->isp_portid >> 16; rp->rftid_portid[1] = fcp->isp_portid >> 8; rp->rftid_portid[2] = fcp->isp_portid; rp->rftid_fc4types[FC4_SCSI >> 5] = 1 << (FC4_SCSI & 0x1f); isp_put_rft_id(isp, rp, (rft_id_t *) &scp[XTXOFF]); if (isp->isp_dblev & ISP_LOGDEBUG1) { isp_print_bytes(isp, "CT Header", QENTRY_LEN, &scp[XTXOFF]); } ISP_MEMZERO(&scp[ZTXOFF], sizeof (ct_hdr_t)); MBSINIT(&mbs, MBOX_EXEC_COMMAND_IOCB_A64, MBLOGALL, 1000000); mbs.param[1] = QENTRY_LEN; mbs.param[2] = DMA_WD1(fcp->isp_scdma + CTXOFF); mbs.param[3] = DMA_WD0(fcp->isp_scdma + CTXOFF); mbs.param[6] = DMA_WD3(fcp->isp_scdma + CTXOFF); mbs.param[7] = DMA_WD2(fcp->isp_scdma + CTXOFF); MEMORYBARRIER(isp, SYNC_SFORDEV, XTXOFF, 2 * QENTRY_LEN, chan); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { FC_SCRATCH_RELEASE(isp, chan); return (-1); } MEMORYBARRIER(isp, SYNC_SFORCPU, ZTXOFF, QENTRY_LEN, chan); pt = &un.plocal; isp_get_ct_pt(isp, (isp_ct_pt_t *) &scp[ZTXOFF], pt); if (isp->isp_dblev & ISP_LOGDEBUG1) { isp_print_bytes(isp, "IOCB response", QENTRY_LEN, pt); } if (pt->ctp_status) { FC_SCRATCH_RELEASE(isp, chan); isp_prt(isp, ISP_LOGWARN, "Chan %d Register FC4 Type CT Passthrough returned 0x%x", chan, pt->ctp_status); return (1); } isp_get_ct_hdr(isp, (ct_hdr_t *) &scp[IGPOFF], ct); FC_SCRATCH_RELEASE(isp, chan); if (ct->ct_cmd_resp == LS_RJT) { isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d Register FC4 Type rejected", chan); return (-1); } else if (ct->ct_cmd_resp == LS_ACC) { isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d Register FC4 Type accepted", chan); return (0); } else { isp_prt(isp, ISP_LOGWARN, "Chan %d Register FC4 Type: 0x%x", chan, ct->ct_cmd_resp); return (-1); } } static uint16_t isp_nxt_handle(ispsoftc_t *isp, int chan, uint16_t handle) { int i; if (handle == NIL_HANDLE) { if (FCPARAM(isp, chan)->isp_topo == TOPO_F_PORT) { handle = 0; } else { handle = SNS_ID+1; } } else { handle += 1; if (handle >= FL_ID && handle <= SNS_ID) { handle = SNS_ID+1; } if (handle >= NPH_RESERVED && handle <= NPH_FL_ID) { handle = NPH_FL_ID+1; } if (ISP_CAP_2KLOGIN(isp)) { if (handle == NPH_MAX_2K) { handle = 0; } } else { if (handle == NPH_MAX) { handle = 0; } } } if (handle == FCPARAM(isp, chan)->isp_loopid) { return (isp_nxt_handle(isp, chan, handle)); } for (i = 0; i < MAX_FC_TARG; i++) { if (FCPARAM(isp, chan)->portdb[i].state == FC_PORTDB_STATE_NIL) { continue; } if (FCPARAM(isp, chan)->portdb[i].handle == handle) { return (isp_nxt_handle(isp, chan, handle)); } } return (handle); } /* * Start a command. Locking is assumed done in the caller. */ int isp_start(XS_T *xs) { ispsoftc_t *isp; uint32_t handle, cdblen; uint8_t local[QENTRY_LEN]; ispreq_t *reqp; void *cdbp, *qep; uint16_t *tptr; int target, dmaresult, hdlidx = 0; XS_INITERR(xs); isp = XS_ISP(xs); /* * Now make sure we're running. */ if (isp->isp_state != ISP_RUNSTATE) { isp_prt(isp, ISP_LOGERR, "Adapter not at RUNSTATE"); XS_SETERR(xs, HBA_BOTCH); return (CMD_COMPLETE); } /* * Check command CDB length, etc.. We really are limited to 16 bytes * for Fibre Channel, but can do up to 44 bytes in parallel SCSI, * but probably only if we're running fairly new firmware (we'll * let the old f/w choke on an extended command queue entry). */ if (XS_CDBLEN(xs) > (IS_FC(isp)? 16 : 44) || XS_CDBLEN(xs) == 0) { isp_prt(isp, ISP_LOGERR, "unsupported cdb length (%d, CDB[0]=0x%x)", XS_CDBLEN(xs), XS_CDBP(xs)[0] & 0xff); XS_SETERR(xs, HBA_BOTCH); return (CMD_COMPLETE); } /* * Translate the target to device handle as appropriate, checking * for correct device state as well. */ target = XS_TGT(xs); if (IS_FC(isp)) { fcparam *fcp = FCPARAM(isp, XS_CHANNEL(xs)); if ((fcp->role & ISP_ROLE_INITIATOR) == 0) { XS_SETERR(xs, HBA_SELTIMEOUT); return (CMD_COMPLETE); } /* * Try again later. */ if (fcp->isp_fwstate != FW_READY || fcp->isp_loopstate != LOOP_READY) { return (CMD_RQLATER); } if (XS_TGT(xs) >= MAX_FC_TARG) { XS_SETERR(xs, HBA_SELTIMEOUT); return (CMD_COMPLETE); } hdlidx = fcp->isp_dev_map[XS_TGT(xs)] - 1; isp_prt(isp, ISP_LOGDEBUG2, "XS_TGT(xs)=%d- hdlidx value %d", XS_TGT(xs), hdlidx); if (hdlidx < 0 || hdlidx >= MAX_FC_TARG) { XS_SETERR(xs, HBA_SELTIMEOUT); return (CMD_COMPLETE); } if (fcp->portdb[hdlidx].state == FC_PORTDB_STATE_ZOMBIE) { return (CMD_RQLATER); } if (fcp->portdb[hdlidx].state != FC_PORTDB_STATE_VALID) { XS_SETERR(xs, HBA_SELTIMEOUT); return (CMD_COMPLETE); } target = fcp->portdb[hdlidx].handle; fcp->portdb[hdlidx].dirty = 1; } else { sdparam *sdp = SDPARAM(isp, XS_CHANNEL(xs)); if ((sdp->role & ISP_ROLE_INITIATOR) == 0) { XS_SETERR(xs, HBA_SELTIMEOUT); return (CMD_COMPLETE); } if (sdp->update) { isp_spi_update(isp, XS_CHANNEL(xs)); } } start_again: qep = isp_getrqentry(isp); if (qep == NULL) { isp_prt(isp, ISP_LOGDEBUG0, "Request Queue Overflow"); XS_SETERR(xs, HBA_BOTCH); return (CMD_EAGAIN); } XS_SETERR(xs, HBA_NOERROR); /* * Now see if we need to synchronize the ISP with respect to anything. * We do dual duty here (cough) for synchronizing for busses other * than which we got here to send a command to. */ reqp = (ispreq_t *) local; ISP_MEMZERO(local, QENTRY_LEN); if (ISP_TST_SENDMARKER(isp, XS_CHANNEL(xs))) { if (IS_24XX(isp)) { isp_marker_24xx_t *m = (isp_marker_24xx_t *) reqp; m->mrk_header.rqs_entry_count = 1; m->mrk_header.rqs_entry_type = RQSTYPE_MARKER; m->mrk_modifier = SYNC_ALL; isp_put_marker_24xx(isp, m, qep); } else { isp_marker_t *m = (isp_marker_t *) reqp; m->mrk_header.rqs_entry_count = 1; m->mrk_header.rqs_entry_type = RQSTYPE_MARKER; m->mrk_target = (XS_CHANNEL(xs) << 7); /* bus # */ m->mrk_modifier = SYNC_ALL; isp_put_marker(isp, m, qep); } ISP_SYNC_REQUEST(isp); ISP_SET_SENDMARKER(isp, XS_CHANNEL(xs), 0); goto start_again; } reqp->req_header.rqs_entry_count = 1; if (IS_24XX(isp)) { reqp->req_header.rqs_entry_type = RQSTYPE_T7RQS; } else if (IS_FC(isp)) { reqp->req_header.rqs_entry_type = RQSTYPE_T2RQS; } else { if (XS_CDBLEN(xs) > 12) { reqp->req_header.rqs_entry_type = RQSTYPE_CMDONLY; } else { reqp->req_header.rqs_entry_type = RQSTYPE_REQUEST; } } if (IS_24XX(isp)) { int ttype; if (XS_TAG_P(xs)) { ttype = XS_TAG_TYPE(xs); } else { if (XS_CDBP(xs)[0] == 0x3) { ttype = REQFLAG_HTAG; } else { ttype = REQFLAG_STAG; } } if (ttype == REQFLAG_OTAG) { ttype = FCP_CMND_TASK_ATTR_ORDERED; } else if (ttype == REQFLAG_HTAG) { ttype = FCP_CMND_TASK_ATTR_HEAD; } else { ttype = FCP_CMND_TASK_ATTR_SIMPLE; } ((ispreqt7_t *)reqp)->req_task_attribute = ttype; } else if (IS_FC(isp)) { /* * See comment in isp_intr */ /* XS_SET_RESID(xs, 0); */ /* * Fibre Channel always requires some kind of tag. * The Qlogic drivers seem be happy not to use a tag, * but this breaks for some devices (IBM drives). */ if (XS_TAG_P(xs)) { ((ispreqt2_t *)reqp)->req_flags = XS_TAG_TYPE(xs); } else { /* * If we don't know what tag to use, use HEAD OF QUEUE * for Request Sense or Simple. */ if (XS_CDBP(xs)[0] == 0x3) /* REQUEST SENSE */ ((ispreqt2_t *)reqp)->req_flags = REQFLAG_HTAG; else ((ispreqt2_t *)reqp)->req_flags = REQFLAG_STAG; } } else { sdparam *sdp = SDPARAM(isp, XS_CHANNEL(xs)); if ((sdp->isp_devparam[target].actv_flags & DPARM_TQING) && XS_TAG_P(xs)) { reqp->req_flags = XS_TAG_TYPE(xs); } } tptr = &reqp->req_time; /* * NB: we do not support long CDBs */ cdblen = XS_CDBLEN(xs); if (IS_SCSI(isp)) { reqp->req_target = target | (XS_CHANNEL(xs) << 7); reqp->req_lun_trn = XS_LUN(xs); cdblen = ISP_MIN(cdblen, sizeof (reqp->req_cdb)); cdbp = reqp->req_cdb; reqp->req_cdblen = cdblen; } else if (IS_24XX(isp)) { ispreqt7_t *t7 = (ispreqt7_t *)local; fcportdb_t *lp; lp = &FCPARAM(isp, XS_CHANNEL(xs))->portdb[hdlidx]; t7->req_nphdl = target; t7->req_tidlo = lp->portid; t7->req_tidhi = lp->portid >> 16; t7->req_vpidx = ISP_GET_VPIDX(isp, XS_CHANNEL(xs)); if (XS_LUN(xs) > 256) { t7->req_lun[0] = XS_LUN(xs) >> 8; t7->req_lun[0] |= 0x40; } t7->req_lun[1] = XS_LUN(xs); tptr = &t7->req_time; cdbp = t7->req_cdb; cdblen = ISP_MIN(cdblen, sizeof (t7->req_cdb)); } else if (ISP_CAP_2KLOGIN(isp)) { ispreqt2e_t *t2e = (ispreqt2e_t *)local; t2e->req_target = target; t2e->req_scclun = XS_LUN(xs); cdbp = t2e->req_cdb; cdblen = ISP_MIN(cdblen, sizeof (t2e->req_cdb)); } else if (ISP_CAP_SCCFW(isp)) { ispreqt2_t *t2 = (ispreqt2_t *)local; t2->req_target = target; t2->req_scclun = XS_LUN(xs); cdbp = t2->req_cdb; cdblen = ISP_MIN(cdblen, sizeof (t2->req_cdb)); } else { ispreqt2_t *t2 = (ispreqt2_t *)local; t2->req_target = target; t2->req_lun_trn = XS_LUN(xs); cdbp = t2->req_cdb; cdblen = ISP_MIN(cdblen, sizeof (t2->req_cdb)); } ISP_MEMCPY(cdbp, XS_CDBP(xs), cdblen); *tptr = XS_TIME(xs) / 1000; if (*tptr == 0 && XS_TIME(xs)) { *tptr = 1; } if (IS_24XX(isp) && *tptr > 0x1999) { *tptr = 0x1999; } if (isp_allocate_xs(isp, xs, &handle)) { isp_prt(isp, ISP_LOGDEBUG0, "out of xflist pointers"); XS_SETERR(xs, HBA_BOTCH); return (CMD_EAGAIN); } /* Whew. Thankfully the same for type 7 requests */ reqp->req_handle = handle; /* * Set up DMA and/or do any platform dependent swizzling of the request entry * so that the Qlogic F/W understands what is being asked of it. * * The callee is responsible for adding all requests at this point. */ dmaresult = ISP_DMASETUP(isp, xs, reqp); if (dmaresult != CMD_QUEUED) { isp_destroy_handle(isp, handle); /* * dmasetup sets actual error in packet, and * return what we were given to return. */ return (dmaresult); } isp_xs_prt(isp, xs, ISP_LOGDEBUG0, "START cmd cdb[0]=0x%x datalen %ld", XS_CDBP(xs)[0], (long) XS_XFRLEN(xs)); isp->isp_nactive++; return (CMD_QUEUED); } /* * isp control * Locks (ints blocked) assumed held. */ int isp_control(ispsoftc_t *isp, ispctl_t ctl, ...) { XS_T *xs; mbreg_t *mbr, mbs; int chan, tgt; uint32_t handle; va_list ap; switch (ctl) { case ISPCTL_RESET_BUS: /* * Issue a bus reset. */ if (IS_24XX(isp)) { isp_prt(isp, ISP_LOGWARN, "RESET BUS NOT IMPLEMENTED"); break; } else if (IS_FC(isp)) { mbs.param[1] = 10; chan = 0; } else { va_start(ap, ctl); chan = va_arg(ap, int); va_end(ap); mbs.param[1] = SDPARAM(isp, chan)->isp_bus_reset_delay; if (mbs.param[1] < 2) { mbs.param[1] = 2; } mbs.param[2] = chan; } MBSINIT(&mbs, MBOX_BUS_RESET, MBLOGALL, 0); ISP_SET_SENDMARKER(isp, chan, 1); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { break; } isp_prt(isp, ISP_LOGINFO, "driver initiated bus reset of bus %d", chan); return (0); case ISPCTL_RESET_DEV: va_start(ap, ctl); chan = va_arg(ap, int); tgt = va_arg(ap, int); va_end(ap); if (IS_24XX(isp)) { uint8_t local[QENTRY_LEN]; isp24xx_tmf_t *tmf; isp24xx_statusreq_t *sp; fcparam *fcp = FCPARAM(isp, chan); fcportdb_t *lp; int hdlidx; hdlidx = fcp->isp_dev_map[tgt] - 1; if (hdlidx < 0 || hdlidx >= MAX_FC_TARG) { isp_prt(isp, ISP_LOGWARN, "Chan %d bad handle %d trying to reset" "target %d", chan, hdlidx, tgt); break; } lp = &fcp->portdb[hdlidx]; if (lp->state != FC_PORTDB_STATE_VALID) { isp_prt(isp, ISP_LOGWARN, "Chan %d handle %d for abort of target %d " "no longer valid", chan, hdlidx, tgt); break; } tmf = (isp24xx_tmf_t *) local; ISP_MEMZERO(tmf, QENTRY_LEN); tmf->tmf_header.rqs_entry_type = RQSTYPE_TSK_MGMT; tmf->tmf_header.rqs_entry_count = 1; tmf->tmf_nphdl = lp->handle; tmf->tmf_delay = 2; tmf->tmf_timeout = 2; tmf->tmf_flags = ISP24XX_TMF_TARGET_RESET; tmf->tmf_tidlo = lp->portid; tmf->tmf_tidhi = lp->portid >> 16; tmf->tmf_vpidx = ISP_GET_VPIDX(isp, chan); isp_prt(isp, ISP_LOGALL, "Chan %d Reset N-Port Handle 0x%04x @ Port 0x%06x", chan, lp->handle, lp->portid); MBSINIT(&mbs, MBOX_EXEC_COMMAND_IOCB_A64, MBLOGALL, 5000000); mbs.param[1] = QENTRY_LEN; mbs.param[2] = DMA_WD1(fcp->isp_scdma); mbs.param[3] = DMA_WD0(fcp->isp_scdma); mbs.param[6] = DMA_WD3(fcp->isp_scdma); mbs.param[7] = DMA_WD2(fcp->isp_scdma); if (FC_SCRATCH_ACQUIRE(isp, chan)) { isp_prt(isp, ISP_LOGERR, sacq); break; } isp_put_24xx_tmf(isp, tmf, fcp->isp_scratch); MEMORYBARRIER(isp, SYNC_SFORDEV, 0, QENTRY_LEN, chan); fcp->sendmarker = 1; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { FC_SCRATCH_RELEASE(isp, chan); break; } MEMORYBARRIER(isp, SYNC_SFORCPU, QENTRY_LEN, QENTRY_LEN, chan); sp = (isp24xx_statusreq_t *) local; isp_get_24xx_response(isp, &((isp24xx_statusreq_t *)fcp->isp_scratch)[1], sp); FC_SCRATCH_RELEASE(isp, chan); if (sp->req_completion_status == 0) { return (0); } isp_prt(isp, ISP_LOGWARN, "Chan %d reset of target %d returned 0x%x", chan, tgt, sp->req_completion_status); break; } else if (IS_FC(isp)) { if (ISP_CAP_2KLOGIN(isp)) { mbs.param[1] = tgt; mbs.ibits = (1 << 10); } else { mbs.param[1] = (tgt << 8); } } else { mbs.param[1] = (chan << 15) | (tgt << 8); } MBSINIT(&mbs, MBOX_ABORT_TARGET, MBLOGALL, 0); mbs.param[2] = 3; /* 'delay', in seconds */ isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { break; } isp_prt(isp, ISP_LOGINFO, "Target %d on Bus %d Reset Succeeded", tgt, chan); ISP_SET_SENDMARKER(isp, chan, 1); return (0); case ISPCTL_ABORT_CMD: va_start(ap, ctl); xs = va_arg(ap, XS_T *); va_end(ap); tgt = XS_TGT(xs); chan = XS_CHANNEL(xs); handle = isp_find_handle(isp, xs); if (handle == 0) { isp_prt(isp, ISP_LOGWARN, "cannot find handle for command to abort"); break; } if (IS_24XX(isp)) { isp24xx_abrt_t local, *ab = &local, *ab2; fcparam *fcp; fcportdb_t *lp; int hdlidx; fcp = FCPARAM(isp, chan); hdlidx = fcp->isp_dev_map[tgt] - 1; if (hdlidx < 0 || hdlidx >= MAX_FC_TARG) { isp_prt(isp, ISP_LOGWARN, "Chan %d bad handle %d trying to abort" "target %d", chan, hdlidx, tgt); break; } lp = &fcp->portdb[hdlidx]; if (lp->state != FC_PORTDB_STATE_VALID) { isp_prt(isp, ISP_LOGWARN, "Chan %d handle %d for abort of target %d " "no longer valid", chan, hdlidx, tgt); break; } isp_prt(isp, ISP_LOGALL, "Chan %d Abort Cmd for N-Port 0x%04x @ Port " "0x%06x %p", chan, lp->handle, lp->portid, xs); ISP_MEMZERO(ab, QENTRY_LEN); ab->abrt_header.rqs_entry_type = RQSTYPE_ABORT_IO; ab->abrt_header.rqs_entry_count = 1; ab->abrt_handle = lp->handle; ab->abrt_cmd_handle = handle; ab->abrt_tidlo = lp->portid; ab->abrt_tidhi = lp->portid >> 16; ab->abrt_vpidx = ISP_GET_VPIDX(isp, chan); ISP_MEMZERO(&mbs, sizeof (mbs)); MBSINIT(&mbs, MBOX_EXEC_COMMAND_IOCB_A64, MBLOGALL, 5000000); mbs.param[1] = QENTRY_LEN; mbs.param[2] = DMA_WD1(fcp->isp_scdma); mbs.param[3] = DMA_WD0(fcp->isp_scdma); mbs.param[6] = DMA_WD3(fcp->isp_scdma); mbs.param[7] = DMA_WD2(fcp->isp_scdma); if (FC_SCRATCH_ACQUIRE(isp, chan)) { isp_prt(isp, ISP_LOGERR, sacq); break; } isp_put_24xx_abrt(isp, ab, fcp->isp_scratch); ab2 = (isp24xx_abrt_t *) &((uint8_t *)fcp->isp_scratch)[QENTRY_LEN]; ab2->abrt_nphdl = 0xdeaf; MEMORYBARRIER(isp, SYNC_SFORDEV, 0, 2 * QENTRY_LEN, chan); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { FC_SCRATCH_RELEASE(isp, chan); break; } MEMORYBARRIER(isp, SYNC_SFORCPU, QENTRY_LEN, QENTRY_LEN, chan); isp_get_24xx_abrt(isp, ab2, ab); FC_SCRATCH_RELEASE(isp, chan); if (ab->abrt_nphdl == ISP24XX_ABRT_OKAY) { return (0); } isp_prt(isp, ISP_LOGWARN, "Chan %d handle %d abort returned 0x%x", chan, hdlidx, ab->abrt_nphdl); break; } else if (IS_FC(isp)) { if (ISP_CAP_SCCFW(isp)) { if (ISP_CAP_2KLOGIN(isp)) { mbs.param[1] = tgt; } else { mbs.param[1] = tgt << 8; } mbs.param[6] = XS_LUN(xs); } else { mbs.param[1] = tgt << 8 | XS_LUN(xs); } } else { mbs.param[1] = (chan << 15) | (tgt << 8) | XS_LUN(xs); } MBSINIT(&mbs, MBOX_ABORT, MBLOGALL & ~MBOX_COMMAND_ERROR, 0); mbs.param[2] = handle; isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { break; } return (0); case ISPCTL_UPDATE_PARAMS: va_start(ap, ctl); chan = va_arg(ap, int); va_end(ap); isp_spi_update(isp, chan); return (0); case ISPCTL_FCLINK_TEST: if (IS_FC(isp)) { int usdelay; va_start(ap, ctl); chan = va_arg(ap, int); usdelay = va_arg(ap, int); va_end(ap); if (usdelay == 0) { usdelay = 250000; } return (isp_fclink_test(isp, chan, usdelay)); } break; case ISPCTL_SCAN_FABRIC: if (IS_FC(isp)) { va_start(ap, ctl); chan = va_arg(ap, int); va_end(ap); return (isp_scan_fabric(isp, chan)); } break; case ISPCTL_SCAN_LOOP: if (IS_FC(isp)) { va_start(ap, ctl); chan = va_arg(ap, int); va_end(ap); return (isp_scan_loop(isp, chan)); } break; case ISPCTL_PDB_SYNC: if (IS_FC(isp)) { va_start(ap, ctl); chan = va_arg(ap, int); va_end(ap); return (isp_pdb_sync(isp, chan)); } break; case ISPCTL_SEND_LIP: if (IS_FC(isp) && !IS_24XX(isp)) { MBSINIT(&mbs, MBOX_INIT_LIP, MBLOGALL, 0); if (ISP_CAP_2KLOGIN(isp)) { mbs.ibits = (1 << 10); } isp_mboxcmd(isp, &mbs); if (mbs.param[0] == MBOX_COMMAND_COMPLETE) { return (0); } } break; case ISPCTL_GET_PDB: if (IS_FC(isp)) { isp_pdb_t *pdb; va_start(ap, ctl); chan = va_arg(ap, int); tgt = va_arg(ap, int); pdb = va_arg(ap, isp_pdb_t *); va_end(ap); return (isp_getpdb(isp, chan, tgt, pdb, 1)); } break; case ISPCTL_GET_NAMES: { uint64_t *wwnn, *wwnp; va_start(ap, ctl); chan = va_arg(ap, int); tgt = va_arg(ap, int); wwnn = va_arg(ap, uint64_t *); wwnp = va_arg(ap, uint64_t *); va_end(ap); if (wwnn == NULL && wwnp == NULL) { break; } if (wwnn) { *wwnn = isp_get_wwn(isp, chan, tgt, 1); if (*wwnn == INI_NONE) { break; } } if (wwnp) { *wwnp = isp_get_wwn(isp, chan, tgt, 0); if (*wwnp == INI_NONE) { break; } } return (0); } case ISPCTL_RUN_MBOXCMD: { va_start(ap, ctl); mbr = va_arg(ap, mbreg_t *); va_end(ap); isp_mboxcmd(isp, mbr); return (0); } case ISPCTL_PLOGX: { isp_plcmd_t *p; int r; va_start(ap, ctl); p = va_arg(ap, isp_plcmd_t *); va_end(ap); if ((p->flags & PLOGX_FLG_CMD_MASK) != PLOGX_FLG_CMD_PLOGI || (p->handle != NIL_HANDLE)) { return (isp_plogx(isp, p->channel, p->handle, p->portid, p->flags, 0)); } do { p->handle = isp_nxt_handle(isp, p->channel, p->handle); r = isp_plogx(isp, p->channel, p->handle, p->portid, p->flags, 0); if ((r & 0xffff) == MBOX_PORT_ID_USED) { p->handle = r >> 16; r = 0; break; } } while ((r & 0xffff) == MBOX_LOOP_ID_USED); return (r); } default: isp_prt(isp, ISP_LOGERR, "Unknown Control Opcode 0x%x", ctl); break; } return (-1); } /* * Interrupt Service Routine(s). * * External (OS) framework has done the appropriate locking, * and the locking will be held throughout this function. */ /* * Limit our stack depth by sticking with the max likely number * of completions on a request queue at any one time. */ #ifndef MAX_REQUESTQ_COMPLETIONS #define MAX_REQUESTQ_COMPLETIONS 32 #endif void isp_intr(ispsoftc_t *isp, uint32_t isr, uint16_t sema, uint16_t mbox) { XS_T *complist[MAX_REQUESTQ_COMPLETIONS], *xs; uint32_t iptr, optr, junk; int i, nlooked = 0, ndone = 0; again: optr = isp->isp_residx; /* * Is this a mailbox related interrupt? * The mailbox semaphore will be nonzero if so. */ if (sema) { fmbox: if (mbox & MBOX_COMMAND_COMPLETE) { isp->isp_intmboxc++; if (isp->isp_mboxbsy) { int obits = isp->isp_obits; isp->isp_mboxtmp[0] = mbox; for (i = 1; i < MAX_MAILBOX(isp); i++) { if ((obits & (1 << i)) == 0) { continue; } isp->isp_mboxtmp[i] = ISP_READ(isp, MBOX_OFF(i)); } if (isp->isp_mbxwrk0) { if (isp_mbox_continue(isp) == 0) { return; } } MBOX_NOTIFY_COMPLETE(isp); } else { isp_prt(isp, ISP_LOGWARN, "mailbox cmd (0x%x) with no waiters", mbox); } } else { i = IS_FC(isp)? isp_parse_async_fc(isp, mbox) : isp_parse_async(isp, mbox); if (i < 0) { return; } } if ((IS_FC(isp) && mbox != ASYNC_RIOZIO_STALL) || isp->isp_state != ISP_RUNSTATE) { goto out; } } /* * We can't be getting this now. */ if (isp->isp_state != ISP_RUNSTATE) { /* * This seems to happen to 23XX and 24XX cards- don't know why. */ if (isp->isp_mboxbsy && isp->isp_lastmbxcmd == MBOX_ABOUT_FIRMWARE) { goto fmbox; } isp_prt(isp, ISP_LOGINFO, "interrupt (ISR=%x SEMA=%x) when not ready", isr, sema); /* * Thank you very much! *Burrrp*! */ ISP_WRITE(isp, isp->isp_respoutrp, ISP_READ(isp, isp->isp_respinrp)); if (IS_24XX(isp)) { ISP_DISABLE_INTS(isp); } goto out; } #ifdef ISP_TARGET_MODE /* * Check for ATIO Queue entries. */ if (IS_24XX(isp)) { iptr = ISP_READ(isp, BIU2400_ATIO_RSPINP); optr = ISP_READ(isp, BIU2400_ATIO_RSPOUTP); while (optr != iptr) { uint8_t qe[QENTRY_LEN]; isphdr_t *hp; uint32_t oop; void *addr; oop = optr; MEMORYBARRIER(isp, SYNC_ATIOQ, oop, QENTRY_LEN, -1); addr = ISP_QUEUE_ENTRY(isp->isp_atioq, oop); isp_get_hdr(isp, addr, (isphdr_t *)qe); hp = (isphdr_t *)qe; switch (hp->rqs_entry_type) { case RQSTYPE_NOTIFY: case RQSTYPE_ATIO: (void) isp_target_notify(isp, addr, &oop); break; default: isp_print_qentry(isp, "?ATIOQ entry?", oop, addr); break; } optr = ISP_NXT_QENTRY(oop, RESULT_QUEUE_LEN(isp)); ISP_WRITE(isp, BIU2400_ATIO_RSPOUTP, optr); } optr = isp->isp_residx; } #endif /* * Get the current Response Queue Out Pointer. * * If we're a 2300 or 2400, we can ask what hardware what it thinks. */ if (IS_23XX(isp) || IS_24XX(isp)) { optr = ISP_READ(isp, isp->isp_respoutrp); /* * Debug: to be taken out eventually */ if (isp->isp_residx != optr) { isp_prt(isp, ISP_LOGINFO, "isp_intr: hard optr=%x, soft optr %x", optr, isp->isp_residx); isp->isp_residx = optr; } } else { optr = isp->isp_residx; } /* * You *must* read the Response Queue In Pointer * prior to clearing the RISC interrupt. * * Debounce the 2300 if revision less than 2. */ if (IS_2100(isp) || (IS_2300(isp) && isp->isp_revision < 2)) { i = 0; do { iptr = ISP_READ(isp, isp->isp_respinrp); junk = ISP_READ(isp, isp->isp_respinrp); } while (junk != iptr && ++i < 1000); if (iptr != junk) { isp_prt(isp, ISP_LOGWARN, "Response Queue Out Pointer Unstable (%x, %x)", iptr, junk); goto out; } } else { iptr = ISP_READ(isp, isp->isp_respinrp); } isp->isp_resodx = iptr; if (optr == iptr && sema == 0) { /* * There are a lot of these- reasons unknown- mostly on * faster Alpha machines. * * I tried delaying after writing HCCR_CMD_CLEAR_RISC_INT to * make sure the old interrupt went away (to avoid 'ringing' * effects), but that didn't stop this from occurring. */ if (IS_24XX(isp)) { junk = 0; } else if (IS_23XX(isp)) { ISP_DELAY(100); iptr = ISP_READ(isp, isp->isp_respinrp); junk = ISP_READ(isp, BIU_R2HSTSLO); } else { junk = ISP_READ(isp, BIU_ISR); } if (optr == iptr) { if (IS_23XX(isp) || IS_24XX(isp)) { ; } else { sema = ISP_READ(isp, BIU_SEMA); mbox = ISP_READ(isp, OUTMAILBOX0); if ((sema & 0x3) && (mbox & 0x8000)) { goto again; } } isp->isp_intbogus++; isp_prt(isp, ISP_LOGDEBUG1, "bogus intr- isr %x (%x) iptr %x optr %x", isr, junk, iptr, optr); } } isp->isp_resodx = iptr; while (optr != iptr) { uint8_t qe[QENTRY_LEN]; ispstatusreq_t *sp = (ispstatusreq_t *) qe; isphdr_t *hp; int buddaboom, etype, scsi_status, completion_status; int req_status_flags, req_state_flags; uint8_t *snsp, *resp; uint32_t rlen, slen; long resid; uint16_t oop; hp = (isphdr_t *) ISP_QUEUE_ENTRY(isp->isp_result, optr); oop = optr; optr = ISP_NXT_QENTRY(optr, RESULT_QUEUE_LEN(isp)); nlooked++; read_again: buddaboom = req_status_flags = req_state_flags = 0; resid = 0L; /* * Synchronize our view of this response queue entry. */ MEMORYBARRIER(isp, SYNC_RESULT, oop, QENTRY_LEN, -1); isp_get_hdr(isp, hp, &sp->req_header); etype = sp->req_header.rqs_entry_type; if (IS_24XX(isp) && etype == RQSTYPE_RESPONSE) { isp24xx_statusreq_t *sp2 = (isp24xx_statusreq_t *)qe; isp_get_24xx_response(isp, (isp24xx_statusreq_t *)hp, sp2); if (isp->isp_dblev & ISP_LOGDEBUG1) { isp_print_bytes(isp, "Response Queue Entry", QENTRY_LEN, sp2); } scsi_status = sp2->req_scsi_status; completion_status = sp2->req_completion_status; req_state_flags = 0; resid = sp2->req_resid; } else if (etype == RQSTYPE_RESPONSE) { isp_get_response(isp, (ispstatusreq_t *) hp, sp); if (isp->isp_dblev & ISP_LOGDEBUG1) { isp_print_bytes(isp, "Response Queue Entry", QENTRY_LEN, sp); } scsi_status = sp->req_scsi_status; completion_status = sp->req_completion_status; req_status_flags = sp->req_status_flags; req_state_flags = sp->req_state_flags; resid = sp->req_resid; } else if (etype == RQSTYPE_RIO1) { isp_rio1_t *rio = (isp_rio1_t *) qe; isp_get_rio1(isp, (isp_rio1_t *) hp, rio); if (isp->isp_dblev & ISP_LOGDEBUG1) { isp_print_bytes(isp, "Response Queue Entry", QENTRY_LEN, rio); } for (i = 0; i < rio->req_header.rqs_seqno; i++) { isp_fastpost_complete(isp, rio->req_handles[i]); } if (isp->isp_fpcchiwater < rio->req_header.rqs_seqno) { isp->isp_fpcchiwater = rio->req_header.rqs_seqno; } ISP_MEMZERO(hp, QENTRY_LEN); /* PERF */ continue; } else if (etype == RQSTYPE_RIO2) { isp_prt(isp, ISP_LOGERR, "dropping RIO2 response\n"); ISP_MEMZERO(hp, QENTRY_LEN); /* PERF */ continue; } else { /* * Somebody reachable via isp_handle_other_response * may have updated the response queue pointers for * us, so we reload our goal index. */ int r; uint32_t tsto = oop; r = isp_handle_other_response(isp, etype, hp, &tsto); if (r < 0) { goto read_again; } /* * If somebody updated the output pointer, then reset * optr to be one more than the updated amount. */ while (tsto != oop) { optr = ISP_NXT_QENTRY(tsto, RESULT_QUEUE_LEN(isp)); } if (r > 0) { ISP_WRITE(isp, isp->isp_respoutrp, optr); ISP_MEMZERO(hp, QENTRY_LEN); /* PERF */ continue; } /* * After this point, we'll just look at the header as * we don't know how to deal with the rest of the * response. */ /* * It really has to be a bounced request just copied * from the request queue to the response queue. If * not, something bad has happened. */ if (etype != RQSTYPE_REQUEST) { isp_prt(isp, ISP_LOGERR, notresp, etype, oop, optr, nlooked); isp_print_bytes(isp, "Request Queue Entry", QENTRY_LEN, sp); ISP_MEMZERO(hp, QENTRY_LEN); /* PERF */ continue; } buddaboom = 1; scsi_status = sp->req_scsi_status; completion_status = sp->req_completion_status; req_status_flags = sp->req_status_flags; req_state_flags = sp->req_state_flags; resid = sp->req_resid; } if (sp->req_header.rqs_flags & RQSFLAG_MASK) { if (sp->req_header.rqs_flags & RQSFLAG_CONTINUATION) { isp_print_bytes(isp, "unexpected continuation segment", QENTRY_LEN, sp); ISP_WRITE(isp, isp->isp_respoutrp, optr); continue; } if (sp->req_header.rqs_flags & RQSFLAG_FULL) { isp_prt(isp, ISP_LOGDEBUG0, "internal queues full"); /* * We'll synthesize a QUEUE FULL message below. */ } if (sp->req_header.rqs_flags & RQSFLAG_BADHEADER) { isp_print_bytes(isp, "bad header flag", QENTRY_LEN, sp); buddaboom++; } if (sp->req_header.rqs_flags & RQSFLAG_BADPACKET) { isp_print_bytes(isp, "bad request packet", QENTRY_LEN, sp); buddaboom++; } if (sp->req_header.rqs_flags & RQSFLAG_BADCOUNT) { isp_print_bytes(isp, "invalid entry count", QENTRY_LEN, sp); buddaboom++; } if (sp->req_header.rqs_flags & RQSFLAG_BADORDER) { isp_print_bytes(isp, "invalid IOCB ordering", QENTRY_LEN, sp); ISP_WRITE(isp, isp->isp_respoutrp, optr); continue; } } if (!ISP_VALID_HANDLE(isp, sp->req_handle)) { isp_prt(isp, ISP_LOGERR, "bad request handle 0x%x (iocb type 0x%x)", sp->req_handle, etype); ISP_MEMZERO(hp, QENTRY_LEN); /* PERF */ ISP_WRITE(isp, isp->isp_respoutrp, optr); continue; } xs = isp_find_xs(isp, sp->req_handle); if (xs == NULL) { uint8_t ts = completion_status & 0xff; /* * Only whine if this isn't the expected fallout of * aborting the command or resetting the target. */ if (etype != RQSTYPE_RESPONSE) { isp_prt(isp, ISP_LOGERR, "cannot find handle 0x%x (type 0x%x)", sp->req_handle, etype); } else if (ts != RQCS_ABORTED && ts != RQCS_RESET_OCCURRED) { isp_prt(isp, ISP_LOGERR, "cannot find handle 0x%x (status 0x%x)", sp->req_handle, ts); } ISP_MEMZERO(hp, QENTRY_LEN); /* PERF */ ISP_WRITE(isp, isp->isp_respoutrp, optr); continue; } if (req_status_flags & RQSTF_BUS_RESET) { XS_SETERR(xs, HBA_BUSRESET); ISP_SET_SENDMARKER(isp, XS_CHANNEL(xs), 1); } if (buddaboom) { XS_SETERR(xs, HBA_BOTCH); } resp = NULL; rlen = 0; snsp = NULL; slen = 0; if (IS_24XX(isp) && (scsi_status & (RQCS_RV|RQCS_SV)) != 0) { resp = ((isp24xx_statusreq_t *)sp)->req_rsp_sense; rlen = ((isp24xx_statusreq_t *)sp)->req_response_len; } else if (IS_FC(isp) && (scsi_status & RQCS_RV) != 0) { resp = sp->req_response; rlen = sp->req_response_len; } if (IS_FC(isp) && (scsi_status & RQCS_SV) != 0) { /* * Fibre Channel F/W doesn't say we got status * if there's Sense Data instead. I guess they * think it goes w/o saying. */ req_state_flags |= RQSF_GOT_STATUS|RQSF_GOT_SENSE; if (IS_24XX(isp)) { snsp = ((isp24xx_statusreq_t *)sp)->req_rsp_sense; snsp += rlen; slen = ((isp24xx_statusreq_t *)sp)->req_sense_len; } else { snsp = sp->req_sense_data; slen = sp->req_sense_len; } } else if (IS_SCSI(isp) && (req_state_flags & RQSF_GOT_SENSE)) { snsp = sp->req_sense_data; slen = sp->req_sense_len; } if (req_state_flags & RQSF_GOT_STATUS) { *XS_STSP(xs) = scsi_status & 0xff; } switch (etype) { case RQSTYPE_RESPONSE: if (resp && rlen >= 4 && resp[FCP_RSPNS_CODE_OFFSET] != 0) { const char *ptr; char lb[64]; const char *rnames[6] = { "Task Management Function Done", "Data Length Differs From Burst Length", "Invalid FCP Cmnd", "FCP DATA RO mismatch with FCP DATA_XFR_RDY RO", "Task Management Function Rejected", "Task Management Function Failed", }; if (resp[FCP_RSPNS_CODE_OFFSET] > 5) { ISP_SNPRINTF(lb, sizeof lb, "Unknown FCP Response Code 0x%x", resp[FCP_RSPNS_CODE_OFFSET]); ptr = lb; } else { ptr = rnames[resp[FCP_RSPNS_CODE_OFFSET]]; } isp_xs_prt(isp, xs, ISP_LOGWARN, "FCP RESPONSE, LENGTH %u: %s CDB0=0x%02x", rlen, ptr, XS_CDBP(xs)[0] & 0xff); if (resp[FCP_RSPNS_CODE_OFFSET] != 0) { XS_SETERR(xs, HBA_BOTCH); } } if (IS_24XX(isp)) { isp_parse_status_24xx(isp, (isp24xx_statusreq_t *)sp, xs, &resid); } else { isp_parse_status(isp, (void *)sp, xs, &resid); } if ((XS_NOERR(xs) || XS_ERR(xs) == HBA_NOERROR) && (*XS_STSP(xs) == SCSI_BUSY)) { XS_SETERR(xs, HBA_TGTBSY); } if (IS_SCSI(isp)) { XS_SET_RESID(xs, resid); /* * A new synchronous rate was negotiated for * this target. Mark state such that we'll go * look up that which has changed later. */ if (req_status_flags & RQSTF_NEGOTIATION) { int t = XS_TGT(xs); sdparam *sdp = SDPARAM(isp, XS_CHANNEL(xs)); sdp->isp_devparam[t].dev_refresh = 1; sdp->update = 1; } } else { if (req_status_flags & RQSF_XFER_COMPLETE) { XS_SET_RESID(xs, 0); } else if (scsi_status & RQCS_RESID) { XS_SET_RESID(xs, resid); } else { XS_SET_RESID(xs, 0); } } if (snsp && slen) { XS_SAVE_SENSE(xs, snsp, slen); } else if ((req_status_flags & RQSF_GOT_STATUS) && (scsi_status & 0xff) == SCSI_CHECK && IS_FC(isp)) { isp_prt(isp, ISP_LOGWARN, "CHECK CONDITION w/o sense data for CDB=0x%x", XS_CDBP(xs)[0] & 0xff); isp_print_bytes(isp, "CC with no Sense", QENTRY_LEN, qe); } isp_prt(isp, ISP_LOGDEBUG2, "asked for %ld got raw resid %ld settled for %ld", (long) XS_XFRLEN(xs), resid, (long) XS_GET_RESID(xs)); break; case RQSTYPE_REQUEST: case RQSTYPE_A64: case RQSTYPE_T2RQS: case RQSTYPE_T3RQS: case RQSTYPE_T7RQS: if (!IS_24XX(isp) && (sp->req_header.rqs_flags & RQSFLAG_FULL)) { /* * Force Queue Full status. */ *XS_STSP(xs) = SCSI_QFULL; XS_SETERR(xs, HBA_NOERROR); } else if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_BOTCH); } XS_SET_RESID(xs, XS_XFRLEN(xs)); break; default: isp_print_bytes(isp, "Unhandled Response Type", QENTRY_LEN, qe); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_BOTCH); } break; } /* * Free any DMA resources. As a side effect, this may * also do any cache flushing necessary for data coherence. */ if (XS_XFRLEN(xs)) { ISP_DMAFREE(isp, xs, sp->req_handle); } isp_destroy_handle(isp, sp->req_handle); if (((isp->isp_dblev & (ISP_LOGDEBUG1|ISP_LOGDEBUG2|ISP_LOGDEBUG3))) || ((isp->isp_dblev & (ISP_LOGDEBUG0|ISP_LOG_CWARN) && ((!XS_NOERR(xs)) || (*XS_STSP(xs) != SCSI_GOOD))))) { isp_prt_endcmd(isp, xs); } if (isp->isp_nactive > 0) { isp->isp_nactive--; } complist[ndone++] = xs; /* defer completion call until later */ ISP_MEMZERO(hp, QENTRY_LEN); /* PERF */ if (ndone == MAX_REQUESTQ_COMPLETIONS) { break; } } /* * If we looked at any commands, then it's valid to find out * what the outpointer is. It also is a trigger to update the * ISP's notion of what we've seen so far. */ if (nlooked) { ISP_WRITE(isp, isp->isp_respoutrp, optr); /* * While we're at it, read the requst queue out pointer. */ isp->isp_reqodx = ISP_READ(isp, isp->isp_rqstoutrp); if (isp->isp_rscchiwater < ndone) { isp->isp_rscchiwater = ndone; } } out: if (IS_24XX(isp)) { ISP_WRITE(isp, BIU2400_HCCR, HCCR_2400_CMD_CLEAR_RISC_INT); } else { ISP_WRITE(isp, HCCR, HCCR_CMD_CLEAR_RISC_INT); ISP_WRITE(isp, BIU_SEMA, 0); } isp->isp_residx = optr; for (i = 0; i < ndone; i++) { xs = complist[i]; if (xs) { isp->isp_rsltccmplt++; isp_done(xs); } } } /* * Support routines. */ void isp_prt_endcmd(ispsoftc_t *isp, XS_T *xs) { char cdbstr[16 * 5 + 1]; int i, lim; lim = XS_CDBLEN(xs) > 16? 16 : XS_CDBLEN(xs); ISP_SNPRINTF(cdbstr, sizeof (cdbstr), "0x%02x ", XS_CDBP(xs)[0]); for (i = 1; i < lim; i++) { ISP_SNPRINTF(cdbstr, sizeof (cdbstr), "%s0x%02x ", cdbstr, XS_CDBP(xs)[i]); } if (XS_SENSE_VALID(xs)) { isp_xs_prt(isp, xs, ISP_LOGALL, "FIN dl%d resid %ld CDB=%s KEY/ASC/ASCQ=0x%02x/0x%02x/0x%02x", XS_XFRLEN(xs), (long) XS_GET_RESID(xs), cdbstr, XS_SNSKEY(xs), XS_SNSASC(xs), XS_SNSASCQ(xs)); } else { isp_xs_prt(isp, xs, ISP_LOGALL, "FIN dl%d resid %ld CDB=%s STS 0x%x XS_ERR=0x%x", XS_XFRLEN(xs), (long) XS_GET_RESID(xs), cdbstr, *XS_STSP(xs), XS_ERR(xs)); } } /* * Parse an ASYNC mailbox complete * * Return non-zero if the event has been acknowledged. */ static int isp_parse_async(ispsoftc_t *isp, uint16_t mbox) { int acked = 0; uint32_t h1 = 0, h2 = 0; uint16_t chan = 0; /* * Pick up the channel, but not if this is a ASYNC_RIO32_2, * where Mailboxes 6/7 have the second handle. */ if (mbox != ASYNC_RIO32_2) { if (IS_DUALBUS(isp)) { chan = ISP_READ(isp, OUTMAILBOX6); } } isp_prt(isp, ISP_LOGDEBUG2, "Async Mbox 0x%x", mbox); switch (mbox) { case ASYNC_BUS_RESET: ISP_SET_SENDMARKER(isp, chan, 1); #ifdef ISP_TARGET_MODE if (isp_target_async(isp, chan, mbox)) { acked = 1; } #endif isp_async(isp, ISPASYNC_BUS_RESET, chan); break; case ASYNC_SYSTEM_ERROR: isp->isp_dead = 1; isp->isp_state = ISP_CRASHED; /* * Were we waiting for a mailbox command to complete? * If so, it's dead, so wake up the waiter. */ if (isp->isp_mboxbsy) { isp->isp_obits = 1; isp->isp_mboxtmp[0] = MBOX_HOST_INTERFACE_ERROR; MBOX_NOTIFY_COMPLETE(isp); } /* * It's up to the handler for isp_async to reinit stuff and * restart the firmware */ isp_async(isp, ISPASYNC_FW_CRASH); acked = 1; break; case ASYNC_RQS_XFER_ERR: isp_prt(isp, ISP_LOGERR, "Request Queue Transfer Error"); break; case ASYNC_RSP_XFER_ERR: isp_prt(isp, ISP_LOGERR, "Response Queue Transfer Error"); break; case ASYNC_QWAKEUP: /* * We've just been notified that the Queue has woken up. * We don't need to be chatty about this- just unlatch things * and move on. */ mbox = ISP_READ(isp, isp->isp_rqstoutrp); break; case ASYNC_TIMEOUT_RESET: isp_prt(isp, ISP_LOGWARN, "timeout initiated SCSI bus reset of chan %d", chan); ISP_SET_SENDMARKER(isp, chan, 1); #ifdef ISP_TARGET_MODE if (isp_target_async(isp, chan, mbox)) { acked = 1; } #endif break; case ASYNC_DEVICE_RESET: isp_prt(isp, ISP_LOGINFO, "device reset on chan %d", chan); ISP_SET_SENDMARKER(isp, chan, 1); #ifdef ISP_TARGET_MODE if (isp_target_async(isp, chan, mbox)) { acked = 1; } #endif break; case ASYNC_EXTMSG_UNDERRUN: isp_prt(isp, ISP_LOGWARN, "extended message underrun"); break; case ASYNC_SCAM_INT: isp_prt(isp, ISP_LOGINFO, "SCAM interrupt"); break; case ASYNC_HUNG_SCSI: isp_prt(isp, ISP_LOGERR, "stalled SCSI Bus after DATA Overrun"); /* XXX: Need to issue SCSI reset at this point */ break; case ASYNC_KILLED_BUS: isp_prt(isp, ISP_LOGERR, "SCSI Bus reset after DATA Overrun"); break; case ASYNC_BUS_TRANSIT: mbox = ISP_READ(isp, OUTMAILBOX2); switch (mbox & SXP_PINS_MODE_MASK) { case SXP_PINS_LVD_MODE: isp_prt(isp, ISP_LOGINFO, "Transition to LVD mode"); SDPARAM(isp, chan)->isp_diffmode = 0; SDPARAM(isp, chan)->isp_ultramode = 0; SDPARAM(isp, chan)->isp_lvdmode = 1; break; case SXP_PINS_HVD_MODE: isp_prt(isp, ISP_LOGINFO, "Transition to Differential mode"); SDPARAM(isp, chan)->isp_diffmode = 1; SDPARAM(isp, chan)->isp_ultramode = 0; SDPARAM(isp, chan)->isp_lvdmode = 0; break; case SXP_PINS_SE_MODE: isp_prt(isp, ISP_LOGINFO, "Transition to Single Ended mode"); SDPARAM(isp, chan)->isp_diffmode = 0; SDPARAM(isp, chan)->isp_ultramode = 1; SDPARAM(isp, chan)->isp_lvdmode = 0; break; default: isp_prt(isp, ISP_LOGWARN, "Transition to Unknown Mode 0x%x", mbox); break; } /* * XXX: Set up to renegotiate again! */ /* Can only be for a 1080... */ ISP_SET_SENDMARKER(isp, chan, 1); break; case ASYNC_CMD_CMPLT: case ASYNC_RIO32_1: if (!IS_ULTRA3(isp)) { isp_prt(isp, ISP_LOGERR, "unexpected fast posting completion"); break; } /* FALLTHROUGH */ h1 = (ISP_READ(isp, OUTMAILBOX2) << 16) | ISP_READ(isp, OUTMAILBOX1); break; case ASYNC_RIO32_2: h1 = (ISP_READ(isp, OUTMAILBOX2) << 16) | ISP_READ(isp, OUTMAILBOX1); h2 = (ISP_READ(isp, OUTMAILBOX7) << 16) | ISP_READ(isp, OUTMAILBOX6); break; case ASYNC_RIO16_5: case ASYNC_RIO16_4: case ASYNC_RIO16_3: case ASYNC_RIO16_2: case ASYNC_RIO16_1: isp_prt(isp, ISP_LOGERR, "unexpected 16 bit RIO handle"); break; default: isp_prt(isp, ISP_LOGWARN, "%s: unhandled async code 0x%x", __func__, mbox); break; } if (h1 || h2) { isp_prt(isp, ISP_LOGDEBUG3, "fast post/rio completion of 0x%08x", h1); isp_fastpost_complete(isp, h1); if (h2) { isp_prt(isp, ISP_LOGDEBUG3, "fast post/rio completion of 0x%08x", h2); isp_fastpost_complete(isp, h2); if (isp->isp_fpcchiwater < 2) { isp->isp_fpcchiwater = 2; } } else { if (isp->isp_fpcchiwater < 1) { isp->isp_fpcchiwater = 1; } } } else { isp->isp_intoasync++; } return (acked); } #define GET_24XX_BUS(isp, chan, msg) \ if (IS_24XX(isp)) { \ chan = ISP_READ(isp, OUTMAILBOX3) & 0xff; \ if (chan >= isp->isp_nchan) { \ isp_prt(isp, ISP_LOGERR, "bogus channel %u for %s at line %d", chan, msg, __LINE__); \ break; \ } \ } static int isp_parse_async_fc(ispsoftc_t *isp, uint16_t mbox) { int acked = 0; uint16_t chan; if (IS_DUALBUS(isp)) { chan = ISP_READ(isp, OUTMAILBOX6); } else { chan = 0; } isp_prt(isp, ISP_LOGDEBUG2, "Async Mbox 0x%x", mbox); switch (mbox) { case ASYNC_SYSTEM_ERROR: isp->isp_dead = 1; isp->isp_state = ISP_CRASHED; FCPARAM(isp, chan)->isp_loopstate = LOOP_NIL; FCPARAM(isp, chan)->isp_fwstate = FW_CONFIG_WAIT; /* * Were we waiting for a mailbox command to complete? * If so, it's dead, so wake up the waiter. */ if (isp->isp_mboxbsy) { isp->isp_obits = 1; isp->isp_mboxtmp[0] = MBOX_HOST_INTERFACE_ERROR; MBOX_NOTIFY_COMPLETE(isp); } /* * It's up to the handler for isp_async to reinit stuff and * restart the firmware */ isp_async(isp, ISPASYNC_FW_CRASH); acked = 1; break; case ASYNC_RQS_XFER_ERR: isp_prt(isp, ISP_LOGERR, "Request Queue Transfer Error"); break; case ASYNC_RSP_XFER_ERR: isp_prt(isp, ISP_LOGERR, "Response Queue Transfer Error"); break; case ASYNC_QWAKEUP: #ifdef ISP_TARGET_MODE if (IS_24XX(isp)) { isp_prt(isp, ISP_LOGERR, "ATIO Queue Transfer Error"); break; } #endif isp_prt(isp, ISP_LOGERR, "%s: unexpected ASYNC_QWAKEUP code", __func__); break; case ASYNC_CMD_CMPLT: isp_fastpost_complete(isp, (ISP_READ(isp, OUTMAILBOX2) << 16) | ISP_READ(isp, OUTMAILBOX1)); if (isp->isp_fpcchiwater < 1) { isp->isp_fpcchiwater = 1; } break; case ASYNC_RIOZIO_STALL: break; case ASYNC_CTIO_DONE: #ifdef ISP_TARGET_MODE if (isp_target_async(isp, (ISP_READ(isp, OUTMAILBOX2) << 16) | ISP_READ(isp, OUTMAILBOX1), mbox)) { acked = 1; } else { isp->isp_fphccmplt++; } #else isp_prt(isp, ISP_LOGWARN, "unexpected ASYNC CTIO done"); #endif break; case ASYNC_LIP_ERROR: case ASYNC_LIP_F8: case ASYNC_LIP_OCCURRED: case ASYNC_PTPMODE: /* * These are broadcast events that have to be sent across * all active channels. */ for (chan = 0; chan < isp->isp_nchan; chan++) { fcparam *fcp = FCPARAM(isp, chan); int topo = fcp->isp_topo; if (fcp->role == ISP_ROLE_NONE) { continue; } fcp->isp_fwstate = FW_CONFIG_WAIT; fcp->isp_loopstate = LOOP_LIP_RCVD; ISP_SET_SENDMARKER(isp, chan, 1); ISP_MARK_PORTDB(isp, chan, 1); isp_async(isp, ISPASYNC_LIP, chan); #ifdef ISP_TARGET_MODE if (isp_target_async(isp, chan, mbox)) { acked = 1; } #endif /* * We've had problems with data corruption occuring on * commands that complete (with no apparent error) after * we receive a LIP. This has been observed mostly on * Local Loop topologies. To be safe, let's just mark * all active initiator commands as dead. */ if (topo == TOPO_NL_PORT || topo == TOPO_FL_PORT) { int i, j; for (i = j = 0; i < isp->isp_maxcmds; i++) { XS_T *xs; isp_hdl_t *hdp; hdp = &isp->isp_xflist[i]; if (ISP_H2HT(hdp->handle) != ISP_HANDLE_INITIATOR) { continue; } xs = hdp->cmd; if (XS_CHANNEL(xs) != chan) { continue; } j++; XS_SETERR(xs, HBA_BUSRESET); } if (j) { isp_prt(isp, ISP_LOGERR, lipd, chan, j); } } } break; case ASYNC_LOOP_UP: /* * This is a broadcast event that has to be sent across * all active channels. */ for (chan = 0; chan < isp->isp_nchan; chan++) { fcparam *fcp = FCPARAM(isp, chan); if (fcp->role == ISP_ROLE_NONE) { continue; } ISP_SET_SENDMARKER(isp, chan, 1); fcp->isp_fwstate = FW_CONFIG_WAIT; fcp->isp_loopstate = LOOP_LIP_RCVD; ISP_MARK_PORTDB(isp, chan, 1); isp_async(isp, ISPASYNC_LOOP_UP, chan); #ifdef ISP_TARGET_MODE if (isp_target_async(isp, chan, mbox)) { acked = 1; } #endif } break; case ASYNC_LOOP_DOWN: /* * This is a broadcast event that has to be sent across * all active channels. */ for (chan = 0; chan < isp->isp_nchan; chan++) { fcparam *fcp = FCPARAM(isp, chan); if (fcp->role == ISP_ROLE_NONE) { continue; } ISP_SET_SENDMARKER(isp, chan, 1); fcp->isp_fwstate = FW_CONFIG_WAIT; fcp->isp_loopstate = LOOP_NIL; ISP_MARK_PORTDB(isp, chan, 1); isp_async(isp, ISPASYNC_LOOP_DOWN, chan); #ifdef ISP_TARGET_MODE if (isp_target_async(isp, chan, mbox)) { acked = 1; } #endif } break; case ASYNC_LOOP_RESET: /* * This is a broadcast event that has to be sent across * all active channels. */ for (chan = 0; chan < isp->isp_nchan; chan++) { fcparam *fcp = FCPARAM(isp, chan); if (fcp->role == ISP_ROLE_NONE) { continue; } ISP_SET_SENDMARKER(isp, chan, 1); fcp->isp_fwstate = FW_CONFIG_WAIT; fcp->isp_loopstate = LOOP_NIL; ISP_MARK_PORTDB(isp, chan, 1); isp_async(isp, ISPASYNC_LOOP_RESET, chan); #ifdef ISP_TARGET_MODE if (isp_target_async(isp, chan, mbox)) { acked = 1; } #endif } break; case ASYNC_PDB_CHANGED: { int nphdl, nlstate, reason; /* * We *should* get a channel out of the 24XX, but we don't seem * to get more than a PDB CHANGED on channel 0, so turn it into * a broadcast event. */ if (IS_24XX(isp)) { nphdl = ISP_READ(isp, OUTMAILBOX1); nlstate = ISP_READ(isp, OUTMAILBOX2); reason = ISP_READ(isp, OUTMAILBOX3) >> 8; } else { nphdl = NIL_HANDLE; nlstate = reason = 0; } for (chan = 0; chan < isp->isp_nchan; chan++) { fcparam *fcp = FCPARAM(isp, chan); if (fcp->role == ISP_ROLE_NONE) { continue; } ISP_SET_SENDMARKER(isp, chan, 1); fcp->isp_loopstate = LOOP_PDB_RCVD; ISP_MARK_PORTDB(isp, chan, 1); isp_async(isp, ISPASYNC_CHANGE_NOTIFY, chan, ISPASYNC_CHANGE_PDB, nphdl, nlstate, reason); } break; } case ASYNC_CHANGE_NOTIFY: { int lochan, hichan; if (ISP_FW_NEWER_THAN(isp, 4, 0, 25) && ISP_CAP_MULTI_ID(isp)) { GET_24XX_BUS(isp, chan, "ASYNC_CHANGE_NOTIFY"); lochan = chan; hichan = chan + 1; } else { lochan = 0; hichan = isp->isp_nchan; } for (chan = lochan; chan < hichan; chan++) { fcparam *fcp = FCPARAM(isp, chan); if (fcp->role == ISP_ROLE_NONE) { continue; } if (fcp->isp_topo == TOPO_F_PORT) { fcp->isp_loopstate = LOOP_LSCAN_DONE; } else { fcp->isp_loopstate = LOOP_PDB_RCVD; } ISP_MARK_PORTDB(isp, chan, 1); isp_async(isp, ISPASYNC_CHANGE_NOTIFY, chan, ISPASYNC_CHANGE_SNS); } break; } case ASYNC_CONNMODE: /* * This only applies to 2100 amd 2200 cards */ if (!IS_2200(isp) && !IS_2100(isp)) { isp_prt(isp, ISP_LOGWARN, "bad card for ASYNC_CONNMODE event"); break; } chan = 0; mbox = ISP_READ(isp, OUTMAILBOX1); ISP_MARK_PORTDB(isp, chan, 1); switch (mbox) { case ISP_CONN_LOOP: isp_prt(isp, ISP_LOGINFO, "Point-to-Point -> Loop mode"); break; case ISP_CONN_PTP: isp_prt(isp, ISP_LOGINFO, "Loop -> Point-to-Point mode"); break; case ISP_CONN_BADLIP: isp_prt(isp, ISP_LOGWARN, "Point-to-Point -> Loop mode (BAD LIP)"); break; case ISP_CONN_FATAL: isp->isp_dead = 1; isp->isp_state = ISP_CRASHED; isp_prt(isp, ISP_LOGERR, "FATAL CONNECTION ERROR"); isp_async(isp, ISPASYNC_FW_CRASH); return (-1); case ISP_CONN_LOOPBACK: isp_prt(isp, ISP_LOGWARN, "Looped Back in Point-to-Point mode"); break; default: isp_prt(isp, ISP_LOGWARN, "Unknown connection mode (0x%x)", mbox); break; } isp_async(isp, ISPASYNC_CHANGE_NOTIFY, chan, ISPASYNC_CHANGE_OTHER); FCPARAM(isp, chan)->sendmarker = 1; FCPARAM(isp, chan)->isp_fwstate = FW_CONFIG_WAIT; FCPARAM(isp, chan)->isp_loopstate = LOOP_LIP_RCVD; break; case ASYNC_RCV_ERR: if (IS_24XX(isp)) { isp_prt(isp, ISP_LOGWARN, "Receive Error"); } else { isp_prt(isp, ISP_LOGWARN, "unexpected ASYNC_RCV_ERR"); } break; case ASYNC_RJT_SENT: /* same as ASYNC_QFULL_SENT */ if (IS_24XX(isp)) { isp_prt(isp, ISP_LOGTDEBUG0, "LS_RJT sent"); break; } else if (IS_2200(isp)) { isp_prt(isp, ISP_LOGTDEBUG0, "QFULL sent"); break; } /* FALLTHROUGH */ default: isp_prt(isp, ISP_LOGWARN, "Unknown Async Code 0x%x", mbox); break; } if (mbox != ASYNC_CTIO_DONE && mbox != ASYNC_CMD_CMPLT) { isp->isp_intoasync++; } return (acked); } /* * Handle other response entries. A pointer to the request queue output * index is here in case we want to eat several entries at once, although * this is not used currently. */ static int isp_handle_other_response(ispsoftc_t *isp, int type, isphdr_t *hp, uint32_t *optrp) { switch (type) { case RQSTYPE_STATUS_CONT: isp_prt(isp, ISP_LOGDEBUG0, "Ignored Continuation Response"); return (1); case RQSTYPE_MARKER: isp_prt(isp, ISP_LOGDEBUG0, "Marker Response"); return (1); case RQSTYPE_ATIO: case RQSTYPE_CTIO: case RQSTYPE_ENABLE_LUN: case RQSTYPE_MODIFY_LUN: case RQSTYPE_NOTIFY: case RQSTYPE_NOTIFY_ACK: case RQSTYPE_CTIO1: case RQSTYPE_ATIO2: case RQSTYPE_CTIO2: case RQSTYPE_CTIO3: case RQSTYPE_CTIO7: case RQSTYPE_ABTS_RCVD: case RQSTYPE_ABTS_RSP: isp->isp_rsltccmplt++; /* count as a response completion */ #ifdef ISP_TARGET_MODE if (isp_target_notify(isp, (ispstatusreq_t *) hp, optrp)) { return (1); } #endif /* FALLTHROUGH */ case RQSTYPE_RPT_ID_ACQ: if (IS_24XX(isp)) { isp_ridacq_t rid; isp_get_ridacq(isp, (isp_ridacq_t *)hp, &rid); if (rid.ridacq_format == 0) { } return (1); } /* FALLTHROUGH */ case RQSTYPE_REQUEST: default: ISP_DELAY(100); if (type != isp_get_response_type(isp, hp)) { /* * This is questionable- we're just papering over * something we've seen on SMP linux in target * mode- we don't really know what's happening * here that causes us to think we've gotten * an entry, but that either the entry isn't * filled out yet or our CPU read data is stale. */ isp_prt(isp, ISP_LOGINFO, "unstable type in response queue"); return (-1); } isp_prt(isp, ISP_LOGWARN, "Unhandled Response Type 0x%x", isp_get_response_type(isp, hp)); return (0); } } static void isp_parse_status(ispsoftc_t *isp, ispstatusreq_t *sp, XS_T *xs, long *rp) { switch (sp->req_completion_status & 0xff) { case RQCS_COMPLETE: if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_NOERROR); } return; case RQCS_INCOMPLETE: if ((sp->req_state_flags & RQSF_GOT_TARGET) == 0) { isp_xs_prt(isp, xs, ISP_LOGDEBUG1, "Selection Timeout"); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_SELTIMEOUT); *rp = XS_XFRLEN(xs); } return; } isp_xs_prt(isp, xs, ISP_LOGERR, "Command Incomplete, state 0x%x", sp->req_state_flags); break; case RQCS_DMA_ERROR: isp_xs_prt(isp, xs, ISP_LOGERR, "DMA Error"); *rp = XS_XFRLEN(xs); break; case RQCS_TRANSPORT_ERROR: { char buf[172]; ISP_SNPRINTF(buf, sizeof (buf), "states=>"); if (sp->req_state_flags & RQSF_GOT_BUS) { ISP_SNPRINTF(buf, sizeof (buf), "%s GOT_BUS", buf); } if (sp->req_state_flags & RQSF_GOT_TARGET) { ISP_SNPRINTF(buf, sizeof (buf), "%s GOT_TGT", buf); } if (sp->req_state_flags & RQSF_SENT_CDB) { ISP_SNPRINTF(buf, sizeof (buf), "%s SENT_CDB", buf); } if (sp->req_state_flags & RQSF_XFRD_DATA) { ISP_SNPRINTF(buf, sizeof (buf), "%s XFRD_DATA", buf); } if (sp->req_state_flags & RQSF_GOT_STATUS) { ISP_SNPRINTF(buf, sizeof (buf), "%s GOT_STS", buf); } if (sp->req_state_flags & RQSF_GOT_SENSE) { ISP_SNPRINTF(buf, sizeof (buf), "%s GOT_SNS", buf); } if (sp->req_state_flags & RQSF_XFER_COMPLETE) { ISP_SNPRINTF(buf, sizeof (buf), "%s XFR_CMPLT", buf); } ISP_SNPRINTF(buf, sizeof (buf), "%s\nstatus=>", buf); if (sp->req_status_flags & RQSTF_DISCONNECT) { ISP_SNPRINTF(buf, sizeof (buf), "%s Disconnect", buf); } if (sp->req_status_flags & RQSTF_SYNCHRONOUS) { ISP_SNPRINTF(buf, sizeof (buf), "%s Sync_xfr", buf); } if (sp->req_status_flags & RQSTF_PARITY_ERROR) { ISP_SNPRINTF(buf, sizeof (buf), "%s Parity", buf); } if (sp->req_status_flags & RQSTF_BUS_RESET) { ISP_SNPRINTF(buf, sizeof (buf), "%s Bus_Reset", buf); } if (sp->req_status_flags & RQSTF_DEVICE_RESET) { ISP_SNPRINTF(buf, sizeof (buf), "%s Device_Reset", buf); } if (sp->req_status_flags & RQSTF_ABORTED) { ISP_SNPRINTF(buf, sizeof (buf), "%s Aborted", buf); } if (sp->req_status_flags & RQSTF_TIMEOUT) { ISP_SNPRINTF(buf, sizeof (buf), "%s Timeout", buf); } if (sp->req_status_flags & RQSTF_NEGOTIATION) { ISP_SNPRINTF(buf, sizeof (buf), "%s Negotiation", buf); } isp_xs_prt(isp, xs, ISP_LOGERR, "Transport Error: %s", buf); *rp = XS_XFRLEN(xs); break; } case RQCS_RESET_OCCURRED: { int chan; isp_xs_prt(isp, xs, ISP_LOGWARN, "Bus Reset destroyed command"); for (chan = 0; chan < isp->isp_nchan; chan++) { FCPARAM(isp, chan)->sendmarker = 1; } if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_BUSRESET); } *rp = XS_XFRLEN(xs); return; } case RQCS_ABORTED: isp_xs_prt(isp, xs, ISP_LOGERR, "Command Aborted"); ISP_SET_SENDMARKER(isp, XS_CHANNEL(xs), 1); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_ABORTED); } return; case RQCS_TIMEOUT: isp_xs_prt(isp, xs, ISP_LOGWARN, "Command timed out"); /* * XXX: Check to see if we logged out of the device. */ if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_CMDTIMEOUT); } return; case RQCS_DATA_OVERRUN: XS_SET_RESID(xs, sp->req_resid); isp_xs_prt(isp, xs, ISP_LOGERR, "data overrun (%ld)", (long) XS_GET_RESID(xs)); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_DATAOVR); } return; case RQCS_COMMAND_OVERRUN: isp_xs_prt(isp, xs, ISP_LOGERR, "command overrun"); break; case RQCS_STATUS_OVERRUN: isp_xs_prt(isp, xs, ISP_LOGERR, "status overrun"); break; case RQCS_BAD_MESSAGE: isp_xs_prt(isp, xs, ISP_LOGERR, "msg not COMMAND COMPLETE after status"); break; case RQCS_NO_MESSAGE_OUT: isp_xs_prt(isp, xs, ISP_LOGERR, "No MESSAGE OUT phase after selection"); break; case RQCS_EXT_ID_FAILED: isp_xs_prt(isp, xs, ISP_LOGERR, "EXTENDED IDENTIFY failed"); break; case RQCS_IDE_MSG_FAILED: isp_xs_prt(isp, xs, ISP_LOGERR, "INITIATOR DETECTED ERROR rejected"); break; case RQCS_ABORT_MSG_FAILED: isp_xs_prt(isp, xs, ISP_LOGERR, "ABORT OPERATION rejected"); break; case RQCS_REJECT_MSG_FAILED: isp_xs_prt(isp, xs, ISP_LOGERR, "MESSAGE REJECT rejected"); break; case RQCS_NOP_MSG_FAILED: isp_xs_prt(isp, xs, ISP_LOGERR, "NOP rejected"); break; case RQCS_PARITY_ERROR_MSG_FAILED: isp_xs_prt(isp, xs, ISP_LOGERR, "MESSAGE PARITY ERROR rejected"); break; case RQCS_DEVICE_RESET_MSG_FAILED: isp_xs_prt(isp, xs, ISP_LOGWARN, "BUS DEVICE RESET rejected"); break; case RQCS_ID_MSG_FAILED: isp_xs_prt(isp, xs, ISP_LOGERR, "IDENTIFY rejected"); break; case RQCS_UNEXP_BUS_FREE: isp_xs_prt(isp, xs, ISP_LOGERR, "Unexpected Bus Free"); break; case RQCS_DATA_UNDERRUN: { if (IS_FC(isp)) { int ru_marked = (sp->req_scsi_status & RQCS_RU) != 0; if (!ru_marked || sp->req_resid > XS_XFRLEN(xs)) { isp_xs_prt(isp, xs, ISP_LOGWARN, bun, XS_XFRLEN(xs), sp->req_resid, (ru_marked)? "marked" : "not marked"); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_BOTCH); } return; } } XS_SET_RESID(xs, sp->req_resid); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_NOERROR); } return; } case RQCS_XACT_ERR1: isp_xs_prt(isp, xs, ISP_LOGERR, "HBA attempted queued transaction with disconnect not set"); break; case RQCS_XACT_ERR2: isp_xs_prt(isp, xs, ISP_LOGERR, "HBA attempted queued transaction to target routine %d", XS_LUN(xs)); break; case RQCS_XACT_ERR3: isp_xs_prt(isp, xs, ISP_LOGERR, "HBA attempted queued cmd when queueing disabled"); break; case RQCS_BAD_ENTRY: isp_prt(isp, ISP_LOGERR, "Invalid IOCB entry type detected"); break; case RQCS_QUEUE_FULL: isp_xs_prt(isp, xs, ISP_LOGDEBUG0, "internal queues full status 0x%x", *XS_STSP(xs)); /* * If QFULL or some other status byte is set, then this * isn't an error, per se. * * Unfortunately, some QLogic f/w writers have, in * some cases, ommitted to *set* status to QFULL. * if (*XS_STSP(xs) != SCSI_GOOD && XS_NOERR(xs)) { XS_SETERR(xs, HBA_NOERROR); return; } * * */ *XS_STSP(xs) = SCSI_QFULL; XS_SETERR(xs, HBA_NOERROR); return; case RQCS_PHASE_SKIPPED: isp_xs_prt(isp, xs, ISP_LOGERR, "SCSI phase skipped"); break; case RQCS_ARQS_FAILED: isp_xs_prt(isp, xs, ISP_LOGERR, "Auto Request Sense Failed"); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_ARQFAIL); } return; case RQCS_WIDE_FAILED: isp_xs_prt(isp, xs, ISP_LOGERR, "Wide Negotiation Failed"); if (IS_SCSI(isp)) { sdparam *sdp = SDPARAM(isp, XS_CHANNEL(xs)); sdp->isp_devparam[XS_TGT(xs)].goal_flags &= ~DPARM_WIDE; sdp->isp_devparam[XS_TGT(xs)].dev_update = 1; sdp->update = 1; } if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_NOERROR); } return; case RQCS_SYNCXFER_FAILED: isp_xs_prt(isp, xs, ISP_LOGERR, "SDTR Message Failed"); if (IS_SCSI(isp)) { sdparam *sdp = SDPARAM(isp, XS_CHANNEL(xs)); sdp += XS_CHANNEL(xs); sdp->isp_devparam[XS_TGT(xs)].goal_flags &= ~DPARM_SYNC; sdp->isp_devparam[XS_TGT(xs)].dev_update = 1; sdp->update = 1; } break; case RQCS_LVD_BUSERR: isp_xs_prt(isp, xs, ISP_LOGERR, "Bad LVD condition"); break; case RQCS_PORT_UNAVAILABLE: /* * No such port on the loop. Moral equivalent of SELTIMEO */ case RQCS_PORT_LOGGED_OUT: { const char *reason; uint8_t sts = sp->req_completion_status & 0xff; /* * It was there (maybe)- treat as a selection timeout. */ if (sts == RQCS_PORT_UNAVAILABLE) { reason = "unavailable"; } else { reason = "logout"; } isp_prt(isp, ISP_LOGINFO, "port %s for target %d", reason, XS_TGT(xs)); /* * If we're on a local loop, force a LIP (which is overkill) * to force a re-login of this unit. If we're on fabric, * then we'll have to log in again as a matter of course. */ if (FCPARAM(isp, 0)->isp_topo == TOPO_NL_PORT || FCPARAM(isp, 0)->isp_topo == TOPO_FL_PORT) { mbreg_t mbs; MBSINIT(&mbs, MBOX_INIT_LIP, MBLOGALL, 0); if (ISP_CAP_2KLOGIN(isp)) { mbs.ibits = (1 << 10); } isp_mboxcmd_qnw(isp, &mbs, 1); } if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_SELTIMEOUT); } return; } case RQCS_PORT_CHANGED: isp_prt(isp, ISP_LOGWARN, "port changed for target %d", XS_TGT(xs)); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_SELTIMEOUT); } return; case RQCS_PORT_BUSY: isp_prt(isp, ISP_LOGWARN, "port busy for target %d", XS_TGT(xs)); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_TGTBSY); } return; default: isp_prt(isp, ISP_LOGERR, "Unknown Completion Status 0x%x", sp->req_completion_status); break; } if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_BOTCH); } } static void isp_parse_status_24xx(ispsoftc_t *isp, isp24xx_statusreq_t *sp, XS_T *xs, long *rp) { int ru_marked, sv_marked; int chan = XS_CHANNEL(xs); switch (sp->req_completion_status) { case RQCS_COMPLETE: if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_NOERROR); } return; case RQCS_DMA_ERROR: isp_xs_prt(isp, xs, ISP_LOGERR, "DMA error"); break; case RQCS_TRANSPORT_ERROR: isp_xs_prt(isp, xs, ISP_LOGERR, "Transport Error"); break; case RQCS_RESET_OCCURRED: isp_xs_prt(isp, xs, ISP_LOGWARN, "reset destroyed command"); FCPARAM(isp, chan)->sendmarker = 1; if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_BUSRESET); } return; case RQCS_ABORTED: isp_xs_prt(isp, xs, ISP_LOGERR, "Command Aborted"); FCPARAM(isp, chan)->sendmarker = 1; if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_ABORTED); } return; case RQCS_TIMEOUT: isp_xs_prt(isp, xs, ISP_LOGWARN, "Command Timed Out"); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_CMDTIMEOUT); } return; case RQCS_DATA_OVERRUN: XS_SET_RESID(xs, sp->req_resid); isp_xs_prt(isp, xs, ISP_LOGERR, "Data Overrun"); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_DATAOVR); } return; case RQCS_24XX_DRE: /* data reassembly error */ isp_prt(isp, ISP_LOGERR, "Chan %d data reassembly error for target %d", chan, XS_TGT(xs)); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_ABORTED); } *rp = XS_XFRLEN(xs); return; case RQCS_24XX_TABORT: /* aborted by target */ isp_prt(isp, ISP_LOGERR, "Chan %d target %d sent ABTS", chan, XS_TGT(xs)); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_ABORTED); } return; case RQCS_DATA_UNDERRUN: ru_marked = (sp->req_scsi_status & RQCS_RU) != 0; /* * We can get an underrun w/o things being marked * if we got a non-zero status. */ sv_marked = (sp->req_scsi_status & (RQCS_SV|RQCS_RV)) != 0; if ((ru_marked == 0 && sv_marked == 0) || (sp->req_resid > XS_XFRLEN(xs))) { isp_xs_prt(isp, xs, ISP_LOGWARN, bun, XS_XFRLEN(xs), sp->req_resid, (ru_marked)? "marked" : "not marked"); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_BOTCH); } return; } XS_SET_RESID(xs, sp->req_resid); isp_xs_prt(isp, xs, ISP_LOGDEBUG0, "Data Underrun (%d) for command 0x%x", sp->req_resid, XS_CDBP(xs)[0] & 0xff); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_NOERROR); } return; case RQCS_PORT_UNAVAILABLE: /* * No such port on the loop. Moral equivalent of SELTIMEO */ case RQCS_PORT_LOGGED_OUT: { const char *reason; uint8_t sts = sp->req_completion_status & 0xff; /* * It was there (maybe)- treat as a selection timeout. */ if (sts == RQCS_PORT_UNAVAILABLE) { reason = "unavailable"; } else { reason = "logout"; } isp_prt(isp, ISP_LOGINFO, "Chan %d port %s for target %d", chan, reason, XS_TGT(xs)); /* * There is no MBOX_INIT_LIP for the 24XX. */ if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_SELTIMEOUT); } return; } case RQCS_PORT_CHANGED: isp_prt(isp, ISP_LOGWARN, "port changed for target %d chan %d", XS_TGT(xs), chan); if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_SELTIMEOUT); } return; case RQCS_24XX_ENOMEM: /* f/w resource unavailable */ isp_prt(isp, ISP_LOGWARN, "f/w resource unavailable for target %d chan %d", XS_TGT(xs), chan); if (XS_NOERR(xs)) { *XS_STSP(xs) = SCSI_BUSY; XS_SETERR(xs, HBA_TGTBSY); } return; case RQCS_24XX_TMO: /* task management overrun */ isp_prt(isp, ISP_LOGWARN, "command for target %d overlapped task management for " "chan %d", XS_TGT(xs), chan); if (XS_NOERR(xs)) { *XS_STSP(xs) = SCSI_BUSY; XS_SETERR(xs, HBA_TGTBSY); } return; default: isp_prt(isp, ISP_LOGERR, "Unknown Completion Status 0x%x on chan %d", sp->req_completion_status, chan); break; } if (XS_NOERR(xs)) { XS_SETERR(xs, HBA_BOTCH); } } static void isp_fastpost_complete(ispsoftc_t *isp, uint32_t fph) { XS_T *xs; if (fph == 0) { return; } xs = isp_find_xs(isp, fph); if (xs == NULL) { isp_prt(isp, ISP_LOGWARN, "Command for fast post handle 0x%x not found", fph); return; } isp_destroy_handle(isp, fph); /* * Since we don't have a result queue entry item, * we must believe that SCSI status is zero and * that all data transferred. */ XS_SET_RESID(xs, 0); *XS_STSP(xs) = SCSI_GOOD; if (XS_XFRLEN(xs)) { ISP_DMAFREE(isp, xs, fph); } if (isp->isp_nactive) { isp->isp_nactive--; } isp->isp_fphccmplt++; isp_done(xs); } static int isp_mbox_continue(ispsoftc_t *isp) { mbreg_t mbs; uint16_t *ptr; uint32_t offset; switch (isp->isp_lastmbxcmd) { case MBOX_WRITE_RAM_WORD: case MBOX_READ_RAM_WORD: case MBOX_WRITE_RAM_WORD_EXTENDED: case MBOX_READ_RAM_WORD_EXTENDED: break; default: return (1); } if (isp->isp_mboxtmp[0] != MBOX_COMMAND_COMPLETE) { isp->isp_mbxwrk0 = 0; return (-1); } /* * Clear the previous interrupt. */ if (IS_24XX(isp)) { ISP_WRITE(isp, BIU2400_HCCR, HCCR_2400_CMD_CLEAR_RISC_INT); } else { ISP_WRITE(isp, HCCR, HCCR_CMD_CLEAR_RISC_INT); ISP_WRITE(isp, BIU_SEMA, 0); } /* * Continue with next word. */ ISP_MEMZERO(&mbs, sizeof (mbs)); ptr = isp->isp_mbxworkp; switch (isp->isp_lastmbxcmd) { case MBOX_WRITE_RAM_WORD: mbs.param[1] = isp->isp_mbxwrk1++; mbs.param[2] = *ptr++; break; case MBOX_READ_RAM_WORD: *ptr++ = isp->isp_mboxtmp[2]; mbs.param[1] = isp->isp_mbxwrk1++; break; case MBOX_WRITE_RAM_WORD_EXTENDED: offset = isp->isp_mbxwrk1; offset |= isp->isp_mbxwrk8 << 16; mbs.param[2] = *ptr++; mbs.param[1] = offset; mbs.param[8] = offset >> 16; isp->isp_mbxwrk1 = ++offset; isp->isp_mbxwrk8 = offset >> 16; break; case MBOX_READ_RAM_WORD_EXTENDED: offset = isp->isp_mbxwrk1; offset |= isp->isp_mbxwrk8 << 16; *ptr++ = isp->isp_mboxtmp[2]; mbs.param[1] = offset; mbs.param[8] = offset >> 16; isp->isp_mbxwrk1 = ++offset; isp->isp_mbxwrk8 = offset >> 16; break; } isp->isp_mbxworkp = ptr; isp->isp_mbxwrk0--; mbs.param[0] = isp->isp_lastmbxcmd; mbs.logval = MBLOGALL; isp_mboxcmd_qnw(isp, &mbs, 0); return (0); } #define HIWRD(x) ((x) >> 16) #define LOWRD(x) ((x) & 0xffff) #define ISPOPMAP(a, b) (((a) << 16) | (b)) static const uint32_t mbpscsi[] = { ISPOPMAP(0x01, 0x01), /* 0x00: MBOX_NO_OP */ ISPOPMAP(0x1f, 0x01), /* 0x01: MBOX_LOAD_RAM */ ISPOPMAP(0x03, 0x01), /* 0x02: MBOX_EXEC_FIRMWARE */ ISPOPMAP(0x1f, 0x01), /* 0x03: MBOX_DUMP_RAM */ ISPOPMAP(0x07, 0x07), /* 0x04: MBOX_WRITE_RAM_WORD */ ISPOPMAP(0x03, 0x07), /* 0x05: MBOX_READ_RAM_WORD */ ISPOPMAP(0x3f, 0x3f), /* 0x06: MBOX_MAILBOX_REG_TEST */ ISPOPMAP(0x07, 0x07), /* 0x07: MBOX_VERIFY_CHECKSUM */ ISPOPMAP(0x01, 0x0f), /* 0x08: MBOX_ABOUT_FIRMWARE */ ISPOPMAP(0x00, 0x00), /* 0x09: */ ISPOPMAP(0x00, 0x00), /* 0x0a: */ ISPOPMAP(0x00, 0x00), /* 0x0b: */ ISPOPMAP(0x00, 0x00), /* 0x0c: */ ISPOPMAP(0x00, 0x00), /* 0x0d: */ ISPOPMAP(0x01, 0x05), /* 0x0e: MBOX_CHECK_FIRMWARE */ ISPOPMAP(0x00, 0x00), /* 0x0f: */ ISPOPMAP(0x1f, 0x1f), /* 0x10: MBOX_INIT_REQ_QUEUE */ ISPOPMAP(0x3f, 0x3f), /* 0x11: MBOX_INIT_RES_QUEUE */ ISPOPMAP(0x0f, 0x0f), /* 0x12: MBOX_EXECUTE_IOCB */ ISPOPMAP(0x03, 0x03), /* 0x13: MBOX_WAKE_UP */ ISPOPMAP(0x01, 0x3f), /* 0x14: MBOX_STOP_FIRMWARE */ ISPOPMAP(0x0f, 0x0f), /* 0x15: MBOX_ABORT */ ISPOPMAP(0x03, 0x03), /* 0x16: MBOX_ABORT_DEVICE */ ISPOPMAP(0x07, 0x07), /* 0x17: MBOX_ABORT_TARGET */ ISPOPMAP(0x07, 0x07), /* 0x18: MBOX_BUS_RESET */ ISPOPMAP(0x03, 0x07), /* 0x19: MBOX_STOP_QUEUE */ ISPOPMAP(0x03, 0x07), /* 0x1a: MBOX_START_QUEUE */ ISPOPMAP(0x03, 0x07), /* 0x1b: MBOX_SINGLE_STEP_QUEUE */ ISPOPMAP(0x03, 0x07), /* 0x1c: MBOX_ABORT_QUEUE */ ISPOPMAP(0x03, 0x4f), /* 0x1d: MBOX_GET_DEV_QUEUE_STATUS */ ISPOPMAP(0x00, 0x00), /* 0x1e: */ ISPOPMAP(0x01, 0x07), /* 0x1f: MBOX_GET_FIRMWARE_STATUS */ ISPOPMAP(0x01, 0x07), /* 0x20: MBOX_GET_INIT_SCSI_ID */ ISPOPMAP(0x01, 0x07), /* 0x21: MBOX_GET_SELECT_TIMEOUT */ ISPOPMAP(0x01, 0xc7), /* 0x22: MBOX_GET_RETRY_COUNT */ ISPOPMAP(0x01, 0x07), /* 0x23: MBOX_GET_TAG_AGE_LIMIT */ ISPOPMAP(0x01, 0x03), /* 0x24: MBOX_GET_CLOCK_RATE */ ISPOPMAP(0x01, 0x07), /* 0x25: MBOX_GET_ACT_NEG_STATE */ ISPOPMAP(0x01, 0x07), /* 0x26: MBOX_GET_ASYNC_DATA_SETUP_TIME */ ISPOPMAP(0x01, 0x07), /* 0x27: MBOX_GET_PCI_PARAMS */ ISPOPMAP(0x03, 0x4f), /* 0x28: MBOX_GET_TARGET_PARAMS */ ISPOPMAP(0x03, 0x0f), /* 0x29: MBOX_GET_DEV_QUEUE_PARAMS */ ISPOPMAP(0x01, 0x07), /* 0x2a: MBOX_GET_RESET_DELAY_PARAMS */ ISPOPMAP(0x00, 0x00), /* 0x2b: */ ISPOPMAP(0x00, 0x00), /* 0x2c: */ ISPOPMAP(0x00, 0x00), /* 0x2d: */ ISPOPMAP(0x00, 0x00), /* 0x2e: */ ISPOPMAP(0x00, 0x00), /* 0x2f: */ ISPOPMAP(0x03, 0x03), /* 0x30: MBOX_SET_INIT_SCSI_ID */ ISPOPMAP(0x07, 0x07), /* 0x31: MBOX_SET_SELECT_TIMEOUT */ ISPOPMAP(0xc7, 0xc7), /* 0x32: MBOX_SET_RETRY_COUNT */ ISPOPMAP(0x07, 0x07), /* 0x33: MBOX_SET_TAG_AGE_LIMIT */ ISPOPMAP(0x03, 0x03), /* 0x34: MBOX_SET_CLOCK_RATE */ ISPOPMAP(0x07, 0x07), /* 0x35: MBOX_SET_ACT_NEG_STATE */ ISPOPMAP(0x07, 0x07), /* 0x36: MBOX_SET_ASYNC_DATA_SETUP_TIME */ ISPOPMAP(0x07, 0x07), /* 0x37: MBOX_SET_PCI_CONTROL_PARAMS */ ISPOPMAP(0x4f, 0x4f), /* 0x38: MBOX_SET_TARGET_PARAMS */ ISPOPMAP(0x0f, 0x0f), /* 0x39: MBOX_SET_DEV_QUEUE_PARAMS */ ISPOPMAP(0x07, 0x07), /* 0x3a: MBOX_SET_RESET_DELAY_PARAMS */ ISPOPMAP(0x00, 0x00), /* 0x3b: */ ISPOPMAP(0x00, 0x00), /* 0x3c: */ ISPOPMAP(0x00, 0x00), /* 0x3d: */ ISPOPMAP(0x00, 0x00), /* 0x3e: */ ISPOPMAP(0x00, 0x00), /* 0x3f: */ ISPOPMAP(0x01, 0x03), /* 0x40: MBOX_RETURN_BIOS_BLOCK_ADDR */ ISPOPMAP(0x3f, 0x01), /* 0x41: MBOX_WRITE_FOUR_RAM_WORDS */ ISPOPMAP(0x03, 0x07), /* 0x42: MBOX_EXEC_BIOS_IOCB */ ISPOPMAP(0x00, 0x00), /* 0x43: */ ISPOPMAP(0x00, 0x00), /* 0x44: */ ISPOPMAP(0x03, 0x03), /* 0x45: SET SYSTEM PARAMETER */ ISPOPMAP(0x01, 0x03), /* 0x46: GET SYSTEM PARAMETER */ ISPOPMAP(0x00, 0x00), /* 0x47: */ ISPOPMAP(0x01, 0xcf), /* 0x48: GET SCAM CONFIGURATION */ ISPOPMAP(0xcf, 0xcf), /* 0x49: SET SCAM CONFIGURATION */ ISPOPMAP(0x03, 0x03), /* 0x4a: MBOX_SET_FIRMWARE_FEATURES */ ISPOPMAP(0x01, 0x03), /* 0x4b: MBOX_GET_FIRMWARE_FEATURES */ ISPOPMAP(0x00, 0x00), /* 0x4c: */ ISPOPMAP(0x00, 0x00), /* 0x4d: */ ISPOPMAP(0x00, 0x00), /* 0x4e: */ ISPOPMAP(0x00, 0x00), /* 0x4f: */ ISPOPMAP(0xdf, 0xdf), /* 0x50: LOAD RAM A64 */ ISPOPMAP(0xdf, 0xdf), /* 0x51: DUMP RAM A64 */ ISPOPMAP(0xdf, 0xff), /* 0x52: INITIALIZE REQUEST QUEUE A64 */ ISPOPMAP(0xef, 0xff), /* 0x53: INITIALIZE RESPONSE QUEUE A64 */ ISPOPMAP(0xcf, 0x01), /* 0x54: EXECUCUTE COMMAND IOCB A64 */ ISPOPMAP(0x07, 0x01), /* 0x55: ENABLE TARGET MODE */ ISPOPMAP(0x03, 0x0f), /* 0x56: GET TARGET STATUS */ ISPOPMAP(0x00, 0x00), /* 0x57: */ ISPOPMAP(0x00, 0x00), /* 0x58: */ ISPOPMAP(0x00, 0x00), /* 0x59: */ ISPOPMAP(0x03, 0x03), /* 0x5a: SET DATA OVERRUN RECOVERY MODE */ ISPOPMAP(0x01, 0x03), /* 0x5b: GET DATA OVERRUN RECOVERY MODE */ ISPOPMAP(0x0f, 0x0f), /* 0x5c: SET HOST DATA */ ISPOPMAP(0x01, 0x01) /* 0x5d: GET NOST DATA */ }; static const char *scsi_mbcmd_names[] = { "NO-OP", "LOAD RAM", "EXEC FIRMWARE", "DUMP RAM", "WRITE RAM WORD", "READ RAM WORD", "MAILBOX REG TEST", "VERIFY CHECKSUM", "ABOUT FIRMWARE", NULL, NULL, NULL, NULL, NULL, "CHECK FIRMWARE", NULL, "INIT REQUEST QUEUE", "INIT RESULT QUEUE", "EXECUTE IOCB", "WAKE UP", "STOP FIRMWARE", "ABORT", "ABORT DEVICE", "ABORT TARGET", "BUS RESET", "STOP QUEUE", "START QUEUE", "SINGLE STEP QUEUE", "ABORT QUEUE", "GET DEV QUEUE STATUS", NULL, "GET FIRMWARE STATUS", "GET INIT SCSI ID", "GET SELECT TIMEOUT", "GET RETRY COUNT", "GET TAG AGE LIMIT", "GET CLOCK RATE", "GET ACT NEG STATE", "GET ASYNC DATA SETUP TIME", "GET PCI PARAMS", "GET TARGET PARAMS", "GET DEV QUEUE PARAMS", "GET RESET DELAY PARAMS", NULL, NULL, NULL, NULL, NULL, "SET INIT SCSI ID", "SET SELECT TIMEOUT", "SET RETRY COUNT", "SET TAG AGE LIMIT", "SET CLOCK RATE", "SET ACT NEG STATE", "SET ASYNC DATA SETUP TIME", "SET PCI CONTROL PARAMS", "SET TARGET PARAMS", "SET DEV QUEUE PARAMS", "SET RESET DELAY PARAMS", NULL, NULL, NULL, NULL, NULL, "RETURN BIOS BLOCK ADDR", "WRITE FOUR RAM WORDS", "EXEC BIOS IOCB", NULL, NULL, "SET SYSTEM PARAMETER", "GET SYSTEM PARAMETER", NULL, "GET SCAM CONFIGURATION", "SET SCAM CONFIGURATION", "SET FIRMWARE FEATURES", "GET FIRMWARE FEATURES", NULL, NULL, NULL, NULL, "LOAD RAM A64", "DUMP RAM A64", "INITIALIZE REQUEST QUEUE A64", "INITIALIZE RESPONSE QUEUE A64", "EXECUTE IOCB A64", "ENABLE TARGET MODE", "GET TARGET MODE STATE", NULL, NULL, NULL, "SET DATA OVERRUN RECOVERY MODE", "GET DATA OVERRUN RECOVERY MODE", "SET HOST DATA", "GET NOST DATA", }; static const uint32_t mbpfc[] = { ISPOPMAP(0x01, 0x01), /* 0x00: MBOX_NO_OP */ ISPOPMAP(0x1f, 0x01), /* 0x01: MBOX_LOAD_RAM */ ISPOPMAP(0x0f, 0x01), /* 0x02: MBOX_EXEC_FIRMWARE */ ISPOPMAP(0xdf, 0x01), /* 0x03: MBOX_DUMP_RAM */ ISPOPMAP(0x07, 0x07), /* 0x04: MBOX_WRITE_RAM_WORD */ ISPOPMAP(0x03, 0x07), /* 0x05: MBOX_READ_RAM_WORD */ ISPOPMAP(0xff, 0xff), /* 0x06: MBOX_MAILBOX_REG_TEST */ ISPOPMAP(0x07, 0x07), /* 0x07: MBOX_VERIFY_CHECKSUM */ ISPOPMAP(0x01, 0x4f), /* 0x08: MBOX_ABOUT_FIRMWARE */ ISPOPMAP(0xdf, 0x01), /* 0x09: MBOX_LOAD_RISC_RAM_2100 */ ISPOPMAP(0xdf, 0x01), /* 0x0a: DUMP RAM */ ISPOPMAP(0x1ff, 0x01), /* 0x0b: MBOX_LOAD_RISC_RAM */ ISPOPMAP(0x00, 0x00), /* 0x0c: */ ISPOPMAP(0x10f, 0x01), /* 0x0d: MBOX_WRITE_RAM_WORD_EXTENDED */ ISPOPMAP(0x01, 0x05), /* 0x0e: MBOX_CHECK_FIRMWARE */ ISPOPMAP(0x10f, 0x05), /* 0x0f: MBOX_READ_RAM_WORD_EXTENDED */ ISPOPMAP(0x1f, 0x11), /* 0x10: MBOX_INIT_REQ_QUEUE */ ISPOPMAP(0x2f, 0x21), /* 0x11: MBOX_INIT_RES_QUEUE */ ISPOPMAP(0x0f, 0x01), /* 0x12: MBOX_EXECUTE_IOCB */ ISPOPMAP(0x03, 0x03), /* 0x13: MBOX_WAKE_UP */ ISPOPMAP(0x01, 0xff), /* 0x14: MBOX_STOP_FIRMWARE */ ISPOPMAP(0x4f, 0x01), /* 0x15: MBOX_ABORT */ ISPOPMAP(0x07, 0x01), /* 0x16: MBOX_ABORT_DEVICE */ ISPOPMAP(0x07, 0x01), /* 0x17: MBOX_ABORT_TARGET */ ISPOPMAP(0x03, 0x03), /* 0x18: MBOX_BUS_RESET */ ISPOPMAP(0x07, 0x05), /* 0x19: MBOX_STOP_QUEUE */ ISPOPMAP(0x07, 0x05), /* 0x1a: MBOX_START_QUEUE */ ISPOPMAP(0x07, 0x05), /* 0x1b: MBOX_SINGLE_STEP_QUEUE */ ISPOPMAP(0x07, 0x05), /* 0x1c: MBOX_ABORT_QUEUE */ ISPOPMAP(0x07, 0x03), /* 0x1d: MBOX_GET_DEV_QUEUE_STATUS */ ISPOPMAP(0x00, 0x00), /* 0x1e: */ ISPOPMAP(0x01, 0x07), /* 0x1f: MBOX_GET_FIRMWARE_STATUS */ ISPOPMAP(0x01, 0x4f), /* 0x20: MBOX_GET_LOOP_ID */ ISPOPMAP(0x00, 0x00), /* 0x21: */ ISPOPMAP(0x01, 0x07), /* 0x22: MBOX_GET_RETRY_COUNT */ ISPOPMAP(0x00, 0x00), /* 0x23: */ ISPOPMAP(0x00, 0x00), /* 0x24: */ ISPOPMAP(0x00, 0x00), /* 0x25: */ ISPOPMAP(0x00, 0x00), /* 0x26: */ ISPOPMAP(0x00, 0x00), /* 0x27: */ ISPOPMAP(0x01, 0x03), /* 0x28: MBOX_GET_FIRMWARE_OPTIONS */ ISPOPMAP(0x03, 0x07), /* 0x29: MBOX_GET_PORT_QUEUE_PARAMS */ ISPOPMAP(0x00, 0x00), /* 0x2a: */ ISPOPMAP(0x00, 0x00), /* 0x2b: */ ISPOPMAP(0x00, 0x00), /* 0x2c: */ ISPOPMAP(0x00, 0x00), /* 0x2d: */ ISPOPMAP(0x00, 0x00), /* 0x2e: */ ISPOPMAP(0x00, 0x00), /* 0x2f: */ ISPOPMAP(0x00, 0x00), /* 0x30: */ ISPOPMAP(0x00, 0x00), /* 0x31: */ ISPOPMAP(0x07, 0x07), /* 0x32: MBOX_SET_RETRY_COUNT */ ISPOPMAP(0x00, 0x00), /* 0x33: */ ISPOPMAP(0x00, 0x00), /* 0x34: */ ISPOPMAP(0x00, 0x00), /* 0x35: */ ISPOPMAP(0x00, 0x00), /* 0x36: */ ISPOPMAP(0x00, 0x00), /* 0x37: */ ISPOPMAP(0x0f, 0x01), /* 0x38: MBOX_SET_FIRMWARE_OPTIONS */ ISPOPMAP(0x0f, 0x07), /* 0x39: MBOX_SET_PORT_QUEUE_PARAMS */ ISPOPMAP(0x00, 0x00), /* 0x3a: */ ISPOPMAP(0x00, 0x00), /* 0x3b: */ ISPOPMAP(0x00, 0x00), /* 0x3c: */ ISPOPMAP(0x00, 0x00), /* 0x3d: */ ISPOPMAP(0x00, 0x00), /* 0x3e: */ ISPOPMAP(0x00, 0x00), /* 0x3f: */ ISPOPMAP(0x03, 0x01), /* 0x40: MBOX_LOOP_PORT_BYPASS */ ISPOPMAP(0x03, 0x01), /* 0x41: MBOX_LOOP_PORT_ENABLE */ ISPOPMAP(0x03, 0x07), /* 0x42: MBOX_GET_RESOURCE_COUNT */ ISPOPMAP(0x01, 0x01), /* 0x43: MBOX_REQUEST_OFFLINE_MODE */ ISPOPMAP(0x00, 0x00), /* 0x44: */ ISPOPMAP(0x00, 0x00), /* 0x45: */ ISPOPMAP(0x00, 0x00), /* 0x46: */ ISPOPMAP(0xcf, 0x03), /* 0x47: GET PORT_DATABASE ENHANCED */ ISPOPMAP(0xcd, 0x01), /* 0x48: MBOX_INIT_FIRMWARE_MULTI_ID */ ISPOPMAP(0xcd, 0x01), /* 0x49: MBOX_GET_VP_DATABASE */ ISPOPMAP(0x2cd, 0x01), /* 0x4a: MBOX_GET_VP_DATABASE_ENTRY */ ISPOPMAP(0x00, 0x00), /* 0x4b: */ ISPOPMAP(0x00, 0x00), /* 0x4c: */ ISPOPMAP(0x00, 0x00), /* 0x4d: */ ISPOPMAP(0x00, 0x00), /* 0x4e: */ ISPOPMAP(0x00, 0x00), /* 0x4f: */ ISPOPMAP(0x00, 0x00), /* 0x50: */ ISPOPMAP(0x00, 0x00), /* 0x51: */ ISPOPMAP(0x00, 0x00), /* 0x52: */ ISPOPMAP(0x00, 0x00), /* 0x53: */ ISPOPMAP(0xcf, 0x01), /* 0x54: EXECUTE IOCB A64 */ ISPOPMAP(0x00, 0x00), /* 0x55: */ ISPOPMAP(0x00, 0x00), /* 0x56: */ ISPOPMAP(0x00, 0x00), /* 0x57: */ ISPOPMAP(0x00, 0x00), /* 0x58: */ ISPOPMAP(0x00, 0x00), /* 0x59: */ ISPOPMAP(0x00, 0x00), /* 0x5a: */ ISPOPMAP(0x03, 0x01), /* 0x5b: MBOX_DRIVER_HEARTBEAT */ ISPOPMAP(0xcf, 0x01), /* 0x5c: MBOX_FW_HEARTBEAT */ ISPOPMAP(0x07, 0x03), /* 0x5d: MBOX_GET_SET_DATA_RATE */ ISPOPMAP(0x00, 0x00), /* 0x5e: */ ISPOPMAP(0x00, 0x00), /* 0x5f: */ ISPOPMAP(0xcd, 0x01), /* 0x60: MBOX_INIT_FIRMWARE */ ISPOPMAP(0x00, 0x00), /* 0x61: */ ISPOPMAP(0x01, 0x01), /* 0x62: MBOX_INIT_LIP */ ISPOPMAP(0xcd, 0x03), /* 0x63: MBOX_GET_FC_AL_POSITION_MAP */ ISPOPMAP(0xcf, 0x01), /* 0x64: MBOX_GET_PORT_DB */ ISPOPMAP(0x07, 0x01), /* 0x65: MBOX_CLEAR_ACA */ ISPOPMAP(0x07, 0x01), /* 0x66: MBOX_TARGET_RESET */ ISPOPMAP(0x07, 0x01), /* 0x67: MBOX_CLEAR_TASK_SET */ ISPOPMAP(0x07, 0x01), /* 0x68: MBOX_ABORT_TASK_SET */ ISPOPMAP(0x01, 0x07), /* 0x69: MBOX_GET_FW_STATE */ ISPOPMAP(0x03, 0xcf), /* 0x6a: MBOX_GET_PORT_NAME */ ISPOPMAP(0xcf, 0x01), /* 0x6b: MBOX_GET_LINK_STATUS */ ISPOPMAP(0x0f, 0x01), /* 0x6c: MBOX_INIT_LIP_RESET */ ISPOPMAP(0x00, 0x00), /* 0x6d: */ ISPOPMAP(0xcf, 0x03), /* 0x6e: MBOX_SEND_SNS */ ISPOPMAP(0x0f, 0x07), /* 0x6f: MBOX_FABRIC_LOGIN */ ISPOPMAP(0x03, 0x01), /* 0x70: MBOX_SEND_CHANGE_REQUEST */ ISPOPMAP(0x03, 0x03), /* 0x71: MBOX_FABRIC_LOGOUT */ ISPOPMAP(0x0f, 0x0f), /* 0x72: MBOX_INIT_LIP_LOGIN */ ISPOPMAP(0x00, 0x00), /* 0x73: */ ISPOPMAP(0x07, 0x01), /* 0x74: LOGIN LOOP PORT */ ISPOPMAP(0xcf, 0x03), /* 0x75: GET PORT/NODE NAME LIST */ ISPOPMAP(0x4f, 0x01), /* 0x76: SET VENDOR ID */ ISPOPMAP(0xcd, 0x01), /* 0x77: INITIALIZE IP MAILBOX */ ISPOPMAP(0x00, 0x00), /* 0x78: */ ISPOPMAP(0x00, 0x00), /* 0x79: */ ISPOPMAP(0x00, 0x00), /* 0x7a: */ ISPOPMAP(0x00, 0x00), /* 0x7b: */ ISPOPMAP(0x4f, 0x03), /* 0x7c: Get ID List */ ISPOPMAP(0xcf, 0x01), /* 0x7d: SEND LFA */ ISPOPMAP(0x0f, 0x01) /* 0x7e: LUN RESET */ }; /* * Footnotes * * (1): this sets bits 21..16 in mailbox register #8, which we nominally * do not access at this time in the core driver. The caller is * responsible for setting this register first (Gross!). The assumption * is that we won't overflow. */ static const char *fc_mbcmd_names[] = { "NO-OP", "LOAD RAM", "EXEC FIRMWARE", "DUMP RAM", "WRITE RAM WORD", "READ RAM WORD", "MAILBOX REG TEST", "VERIFY CHECKSUM", "ABOUT FIRMWARE", "LOAD RAM", "DUMP RAM", "WRITE RAM WORD EXTENDED", NULL, "READ RAM WORD EXTENDED", "CHECK FIRMWARE", NULL, "INIT REQUEST QUEUE", "INIT RESULT QUEUE", "EXECUTE IOCB", "WAKE UP", "STOP FIRMWARE", "ABORT", "ABORT DEVICE", "ABORT TARGET", "BUS RESET", "STOP QUEUE", "START QUEUE", "SINGLE STEP QUEUE", "ABORT QUEUE", "GET DEV QUEUE STATUS", NULL, "GET FIRMWARE STATUS", "GET LOOP ID", NULL, "GET RETRY COUNT", NULL, NULL, NULL, NULL, NULL, "GET FIRMWARE OPTIONS", "GET PORT QUEUE PARAMS", NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, "SET RETRY COUNT", NULL, NULL, NULL, NULL, NULL, "SET FIRMWARE OPTIONS", "SET PORT QUEUE PARAMS", NULL, NULL, NULL, NULL, NULL, NULL, "LOOP PORT BYPASS", "LOOP PORT ENABLE", "GET RESOURCE COUNT", "REQUEST NON PARTICIPATING MODE", NULL, NULL, NULL, "GET PORT DATABASE ENHANCED", "INIT FIRMWARE MULTI ID", "GET VP DATABASE", "GET VP DATABASE ENTRY", NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, "EXECUTE IOCB A64", NULL, NULL, NULL, NULL, NULL, NULL, "DRIVER HEARTBEAT", NULL, "GET/SET DATA RATE", NULL, NULL, "INIT FIRMWARE", NULL, "INIT LIP", "GET FC-AL POSITION MAP", "GET PORT DATABASE", "CLEAR ACA", "TARGET RESET", "CLEAR TASK SET", "ABORT TASK SET", "GET FW STATE", "GET PORT NAME", "GET LINK STATUS", "INIT LIP RESET", NULL, "SEND SNS", "FABRIC LOGIN", "SEND CHANGE REQUEST", "FABRIC LOGOUT", "INIT LIP LOGIN", NULL, "LOGIN LOOP PORT", "GET PORT/NODE NAME LIST", "SET VENDOR ID", "INITIALIZE IP MAILBOX", NULL, NULL, NULL, NULL, "Get ID List", "SEND LFA", "Lun RESET" }; static void isp_mboxcmd_qnw(ispsoftc_t *isp, mbreg_t *mbp, int nodelay) { unsigned int ibits, obits, box, opcode; const uint32_t *mcp; if (IS_FC(isp)) { mcp = mbpfc; } else { mcp = mbpscsi; } opcode = mbp->param[0]; ibits = HIWRD(mcp[opcode]) & NMBOX_BMASK(isp); obits = LOWRD(mcp[opcode]) & NMBOX_BMASK(isp); ibits |= mbp->ibits; obits |= mbp->obits; for (box = 0; box < MAX_MAILBOX(isp); box++) { if (ibits & (1 << box)) { ISP_WRITE(isp, MBOX_OFF(box), mbp->param[box]); } if (nodelay == 0) { isp->isp_mboxtmp[box] = mbp->param[box] = 0; } } if (nodelay == 0) { isp->isp_lastmbxcmd = opcode; isp->isp_obits = obits; isp->isp_mboxbsy = 1; } if (IS_24XX(isp)) { ISP_WRITE(isp, BIU2400_HCCR, HCCR_2400_CMD_SET_HOST_INT); } else { ISP_WRITE(isp, HCCR, HCCR_CMD_SET_HOST_INT); } /* * Oddly enough, if we're not delaying for an answer, * delay a bit to give the f/w a chance to pick up the * command. */ if (nodelay) { ISP_DELAY(1000); } } static void isp_mboxcmd(ispsoftc_t *isp, mbreg_t *mbp) { const char *cname, *xname; char tname[16], mname[16]; unsigned int lim, ibits, obits, box, opcode; const uint32_t *mcp; if (IS_FC(isp)) { mcp = mbpfc; lim = (sizeof (mbpfc) / sizeof (mbpfc[0])); } else { mcp = mbpscsi; lim = (sizeof (mbpscsi) / sizeof (mbpscsi[0])); } if ((opcode = mbp->param[0]) >= lim) { mbp->param[0] = MBOX_INVALID_COMMAND; isp_prt(isp, ISP_LOGERR, "Unknown Command 0x%x", opcode); return; } ibits = HIWRD(mcp[opcode]) & NMBOX_BMASK(isp); obits = LOWRD(mcp[opcode]) & NMBOX_BMASK(isp); /* * Pick up any additional bits that the caller might have set. */ ibits |= mbp->ibits; obits |= mbp->obits; if (ibits == 0 && obits == 0) { mbp->param[0] = MBOX_COMMAND_PARAM_ERROR; isp_prt(isp, ISP_LOGERR, "no parameters for 0x%x", opcode); return; } /* * Get exclusive usage of mailbox registers. */ if (MBOX_ACQUIRE(isp)) { mbp->param[0] = MBOX_REGS_BUSY; goto out; } for (box = 0; box < MAX_MAILBOX(isp); box++) { if (ibits & (1 << box)) { isp_prt(isp, ISP_LOGDEBUG3, "IN mbox %d = 0x%04x", box, mbp->param[box]); ISP_WRITE(isp, MBOX_OFF(box), mbp->param[box]); } isp->isp_mboxtmp[box] = mbp->param[box] = 0; } isp->isp_lastmbxcmd = opcode; /* * We assume that we can't overwrite a previous command. */ isp->isp_obits = obits; isp->isp_mboxbsy = 1; /* * Set Host Interrupt condition so that RISC will pick up mailbox regs. */ if (IS_24XX(isp)) { ISP_WRITE(isp, BIU2400_HCCR, HCCR_2400_CMD_SET_HOST_INT); } else { ISP_WRITE(isp, HCCR, HCCR_CMD_SET_HOST_INT); } /* * While we haven't finished the command, spin our wheels here. */ MBOX_WAIT_COMPLETE(isp, mbp); /* * Did the command time out? */ if (mbp->param[0] == MBOX_TIMEOUT) { isp->isp_mboxbsy = 0; MBOX_RELEASE(isp); goto out; } /* * Copy back output registers. */ for (box = 0; box < MAX_MAILBOX(isp); box++) { if (obits & (1 << box)) { mbp->param[box] = isp->isp_mboxtmp[box]; isp_prt(isp, ISP_LOGDEBUG3, "OUT mbox %d = 0x%04x", box, mbp->param[box]); } } isp->isp_mboxbsy = 0; MBOX_RELEASE(isp); out: if (mbp->logval == 0 || opcode == MBOX_EXEC_FIRMWARE) { return; } cname = (IS_FC(isp))? fc_mbcmd_names[opcode] : scsi_mbcmd_names[opcode]; if (cname == NULL) { cname = tname; ISP_SNPRINTF(tname, sizeof tname, "opcode %x", opcode); } /* * Just to be chatty here... */ xname = NULL; switch (mbp->param[0]) { case MBOX_COMMAND_COMPLETE: break; case MBOX_INVALID_COMMAND: if (mbp->logval & MBLOGMASK(MBOX_COMMAND_COMPLETE)) { xname = "INVALID COMMAND"; } break; case MBOX_HOST_INTERFACE_ERROR: if (mbp->logval & MBLOGMASK(MBOX_HOST_INTERFACE_ERROR)) { xname = "HOST INTERFACE ERROR"; } break; case MBOX_TEST_FAILED: if (mbp->logval & MBLOGMASK(MBOX_TEST_FAILED)) { xname = "TEST FAILED"; } break; case MBOX_COMMAND_ERROR: if (mbp->logval & MBLOGMASK(MBOX_COMMAND_ERROR)) { xname = "COMMAND ERROR"; } break; case MBOX_COMMAND_PARAM_ERROR: if (mbp->logval & MBLOGMASK(MBOX_COMMAND_PARAM_ERROR)) { xname = "COMMAND PARAMETER ERROR"; } break; case MBOX_LOOP_ID_USED: if (mbp->logval & MBLOGMASK(MBOX_LOOP_ID_USED)) { xname = "LOOP ID ALREADY IN USE"; } break; case MBOX_PORT_ID_USED: if (mbp->logval & MBLOGMASK(MBOX_PORT_ID_USED)) { xname = "PORT ID ALREADY IN USE"; } break; case MBOX_ALL_IDS_USED: if (mbp->logval & MBLOGMASK(MBOX_ALL_IDS_USED)) { xname = "ALL LOOP IDS IN USE"; } break; case MBOX_REGS_BUSY: xname = "REGISTERS BUSY"; break; case MBOX_TIMEOUT: xname = "TIMEOUT"; break; default: ISP_SNPRINTF(mname, sizeof mname, "error 0x%x", mbp->param[0]); xname = mname; break; } if (xname) { isp_prt(isp, ISP_LOGALL, "Mailbox Command '%s' failed (%s)", cname, xname); } } static void isp_fw_state(ispsoftc_t *isp, int chan) { if (IS_FC(isp)) { mbreg_t mbs; fcparam *fcp = FCPARAM(isp, chan); MBSINIT(&mbs, MBOX_GET_FW_STATE, MBLOGALL, 0); isp_mboxcmd(isp, &mbs); if (mbs.param[0] == MBOX_COMMAND_COMPLETE) { fcp->isp_fwstate = mbs.param[1]; } } } static void isp_spi_update(ispsoftc_t *isp, int chan) { int tgt; mbreg_t mbs; sdparam *sdp; if (IS_FC(isp)) { /* * There are no 'per-bus' settings for Fibre Channel. */ return; } sdp = SDPARAM(isp, chan); sdp->update = 0; for (tgt = 0; tgt < MAX_TARGETS; tgt++) { uint16_t flags, period, offset; int get; if (sdp->isp_devparam[tgt].dev_enable == 0) { sdp->isp_devparam[tgt].dev_update = 0; sdp->isp_devparam[tgt].dev_refresh = 0; isp_prt(isp, ISP_LOGDEBUG0, "skipping target %d bus %d update", tgt, chan); continue; } /* * If the goal is to update the status of the device, * take what's in goal_flags and try and set the device * toward that. Otherwise, if we're just refreshing the * current device state, get the current parameters. */ MBSINIT(&mbs, 0, MBLOGALL, 0); /* * Refresh overrides set */ if (sdp->isp_devparam[tgt].dev_refresh) { mbs.param[0] = MBOX_GET_TARGET_PARAMS; get = 1; } else if (sdp->isp_devparam[tgt].dev_update) { mbs.param[0] = MBOX_SET_TARGET_PARAMS; /* * Make sure goal_flags has "Renegotiate on Error" * on and "Freeze Queue on Error" off. */ sdp->isp_devparam[tgt].goal_flags |= DPARM_RENEG; sdp->isp_devparam[tgt].goal_flags &= ~DPARM_QFRZ; mbs.param[2] = sdp->isp_devparam[tgt].goal_flags; /* * Insist that PARITY must be enabled * if SYNC or WIDE is enabled. */ if ((mbs.param[2] & (DPARM_SYNC|DPARM_WIDE)) != 0) { mbs.param[2] |= DPARM_PARITY; } if (mbs.param[2] & DPARM_SYNC) { mbs.param[3] = (sdp->isp_devparam[tgt].goal_offset << 8) | (sdp->isp_devparam[tgt].goal_period); } /* * A command completion later that has * RQSTF_NEGOTIATION set can cause * the dev_refresh/announce cycle also. * * Note: It is really important to update our current * flags with at least the state of TAG capabilities- * otherwise we might try and send a tagged command * when we have it all turned off. So change it here * to say that current already matches goal. */ sdp->isp_devparam[tgt].actv_flags &= ~DPARM_TQING; sdp->isp_devparam[tgt].actv_flags |= (sdp->isp_devparam[tgt].goal_flags & DPARM_TQING); isp_prt(isp, ISP_LOGDEBUG0, "bus %d set tgt %d flags 0x%x off 0x%x period 0x%x", chan, tgt, mbs.param[2], mbs.param[3] >> 8, mbs.param[3] & 0xff); get = 0; } else { continue; } mbs.param[1] = (chan << 15) | (tgt << 8); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { continue; } if (get == 0) { sdp->sendmarker = 1; sdp->isp_devparam[tgt].dev_update = 0; sdp->isp_devparam[tgt].dev_refresh = 1; } else { sdp->isp_devparam[tgt].dev_refresh = 0; flags = mbs.param[2]; period = mbs.param[3] & 0xff; offset = mbs.param[3] >> 8; sdp->isp_devparam[tgt].actv_flags = flags; sdp->isp_devparam[tgt].actv_period = period; sdp->isp_devparam[tgt].actv_offset = offset; isp_async(isp, ISPASYNC_NEW_TGT_PARAMS, chan, tgt); } } for (tgt = 0; tgt < MAX_TARGETS; tgt++) { if (sdp->isp_devparam[tgt].dev_update || sdp->isp_devparam[tgt].dev_refresh) { sdp->update = 1; break; } } } static void isp_setdfltsdparm(ispsoftc_t *isp) { int tgt; sdparam *sdp, *sdp1; sdp = SDPARAM(isp, 0); sdp->role = GET_DEFAULT_ROLE(isp, 0); if (IS_DUALBUS(isp)) { sdp1 = sdp + 1; sdp1->role = GET_DEFAULT_ROLE(isp, 1); } else { sdp1 = NULL; } /* * Establish some default parameters. */ sdp->isp_cmd_dma_burst_enable = 0; sdp->isp_data_dma_burst_enabl = 1; sdp->isp_fifo_threshold = 0; sdp->isp_initiator_id = DEFAULT_IID(isp, 0); if (isp->isp_type >= ISP_HA_SCSI_1040) { sdp->isp_async_data_setup = 9; } else { sdp->isp_async_data_setup = 6; } sdp->isp_selection_timeout = 250; sdp->isp_max_queue_depth = MAXISPREQUEST(isp); sdp->isp_tag_aging = 8; sdp->isp_bus_reset_delay = 5; /* * Don't retry selection, busy or queue full automatically- reflect * these back to us. */ sdp->isp_retry_count = 0; sdp->isp_retry_delay = 0; for (tgt = 0; tgt < MAX_TARGETS; tgt++) { sdp->isp_devparam[tgt].exc_throttle = ISP_EXEC_THROTTLE; sdp->isp_devparam[tgt].dev_enable = 1; } /* * The trick here is to establish a default for the default (honk!) * state (goal_flags). Then try and get the current status from * the card to fill in the current state. We don't, in fact, set * the default to the SAFE default state- that's not the goal state. */ for (tgt = 0; tgt < MAX_TARGETS; tgt++) { uint8_t off, per; sdp->isp_devparam[tgt].actv_offset = 0; sdp->isp_devparam[tgt].actv_period = 0; sdp->isp_devparam[tgt].actv_flags = 0; sdp->isp_devparam[tgt].goal_flags = sdp->isp_devparam[tgt].nvrm_flags = DPARM_DEFAULT; /* * We default to Wide/Fast for versions less than a 1040 * (unless it's SBus). */ if (IS_ULTRA3(isp)) { off = ISP_80M_SYNCPARMS >> 8; per = ISP_80M_SYNCPARMS & 0xff; } else if (IS_ULTRA2(isp)) { off = ISP_40M_SYNCPARMS >> 8; per = ISP_40M_SYNCPARMS & 0xff; } else if (IS_1240(isp)) { off = ISP_20M_SYNCPARMS >> 8; per = ISP_20M_SYNCPARMS & 0xff; } else if ((isp->isp_bustype == ISP_BT_SBUS && isp->isp_type < ISP_HA_SCSI_1020A) || (isp->isp_bustype == ISP_BT_PCI && isp->isp_type < ISP_HA_SCSI_1040) || (isp->isp_clock && isp->isp_clock < 60) || (sdp->isp_ultramode == 0)) { off = ISP_10M_SYNCPARMS >> 8; per = ISP_10M_SYNCPARMS & 0xff; } else { off = ISP_20M_SYNCPARMS_1040 >> 8; per = ISP_20M_SYNCPARMS_1040 & 0xff; } sdp->isp_devparam[tgt].goal_offset = sdp->isp_devparam[tgt].nvrm_offset = off; sdp->isp_devparam[tgt].goal_period = sdp->isp_devparam[tgt].nvrm_period = per; } /* * If we're a dual bus card, just copy the data over */ if (sdp1) { *sdp1 = *sdp; sdp1->isp_initiator_id = DEFAULT_IID(isp, 1); } /* * If we've not been told to avoid reading NVRAM, try and read it. * If we're successful reading it, we can then return because NVRAM * will tell us what the desired settings are. Otherwise, we establish * some reasonable 'fake' nvram and goal defaults. */ if ((isp->isp_confopts & ISP_CFG_NONVRAM) == 0) { mbreg_t mbs; if (isp_read_nvram(isp, 0) == 0) { if (IS_DUALBUS(isp)) { if (isp_read_nvram(isp, 1) == 0) { return; } } } MBSINIT(&mbs, MBOX_GET_ACT_NEG_STATE, MBLOGNONE, 0); isp_mboxcmd(isp, &mbs); if (mbs.param[0] != MBOX_COMMAND_COMPLETE) { sdp->isp_req_ack_active_neg = 1; sdp->isp_data_line_active_neg = 1; if (sdp1) { sdp1->isp_req_ack_active_neg = 1; sdp1->isp_data_line_active_neg = 1; } } else { sdp->isp_req_ack_active_neg = (mbs.param[1] >> 4) & 0x1; sdp->isp_data_line_active_neg = (mbs.param[1] >> 5) & 0x1; if (sdp1) { sdp1->isp_req_ack_active_neg = (mbs.param[2] >> 4) & 0x1; sdp1->isp_data_line_active_neg = (mbs.param[2] >> 5) & 0x1; } } } } static void isp_setdfltfcparm(ispsoftc_t *isp, int chan) { fcparam *fcp = FCPARAM(isp, chan); /* * Establish some default parameters. */ fcp->role = GET_DEFAULT_ROLE(isp, chan); fcp->isp_maxalloc = ICB_DFLT_ALLOC; fcp->isp_retry_delay = ICB_DFLT_RDELAY; fcp->isp_retry_count = ICB_DFLT_RCOUNT; fcp->isp_loopid = DEFAULT_LOOPID(isp, chan); fcp->isp_wwnn_nvram = DEFAULT_NODEWWN(isp, chan); fcp->isp_wwpn_nvram = DEFAULT_PORTWWN(isp, chan); fcp->isp_fwoptions = 0; fcp->isp_lasthdl = NIL_HANDLE; if (IS_24XX(isp)) { fcp->isp_fwoptions |= ICB2400_OPT1_FAIRNESS; fcp->isp_fwoptions |= ICB2400_OPT1_HARD_ADDRESS; if (isp->isp_confopts & ISP_CFG_FULL_DUPLEX) { fcp->isp_fwoptions |= ICB2400_OPT1_FULL_DUPLEX; } fcp->isp_fwoptions |= ICB2400_OPT1_BOTH_WWNS; } else { fcp->isp_fwoptions |= ICBOPT_FAIRNESS; fcp->isp_fwoptions |= ICBOPT_PDBCHANGE_AE; fcp->isp_fwoptions |= ICBOPT_HARD_ADDRESS; if (isp->isp_confopts & ISP_CFG_FULL_DUPLEX) { fcp->isp_fwoptions |= ICBOPT_FULL_DUPLEX; } /* * Make sure this is turned off now until we get * extended options from NVRAM */ fcp->isp_fwoptions &= ~ICBOPT_EXTENDED; } /* * Now try and read NVRAM unless told to not do so. * This will set fcparam's isp_wwnn_nvram && isp_wwpn_nvram. */ if ((isp->isp_confopts & ISP_CFG_NONVRAM) == 0) { int i, j = 0; /* * Give a couple of tries at reading NVRAM. */ for (i = 0; i < 2; i++) { j = isp_read_nvram(isp, chan); if (j == 0) { break; } } if (j) { isp->isp_confopts |= ISP_CFG_NONVRAM; } } fcp->isp_wwnn = ACTIVE_NODEWWN(isp, chan); fcp->isp_wwpn = ACTIVE_PORTWWN(isp, chan); isp_prt(isp, ISP_LOGCONFIG, "Chan %d 0x%08x%08x/0x%08x%08x Role %s", chan, (uint32_t) (fcp->isp_wwnn >> 32), (uint32_t) (fcp->isp_wwnn), (uint32_t) (fcp->isp_wwpn >> 32), (uint32_t) (fcp->isp_wwpn), isp_class3_roles[fcp->role]); } /* * Re-initialize the ISP and complete all orphaned commands * with a 'botched' notice. The reset/init routines should * not disturb an already active list of commands. */ void isp_reinit(ispsoftc_t *isp, int do_load_defaults) { int i; isp_reset(isp, do_load_defaults); if (isp->isp_state != ISP_RESETSTATE) { isp_prt(isp, ISP_LOGERR, "%s: cannot reset card", __func__); ISP_DISABLE_INTS(isp); goto cleanup; } isp_init(isp); if (isp->isp_state == ISP_INITSTATE) { isp->isp_state = ISP_RUNSTATE; } if (isp->isp_state != ISP_RUNSTATE) { #ifndef ISP_TARGET_MODE isp_prt(isp, ISP_LOGWARN, "%s: not at runstate", __func__); #endif ISP_DISABLE_INTS(isp); if (IS_FC(isp)) { /* * If we're in ISP_ROLE_NONE, turn off the lasers. */ if (!IS_24XX(isp)) { ISP_WRITE(isp, BIU2100_CSR, BIU2100_FPM0_REGS); ISP_WRITE(isp, FPM_DIAG_CONFIG, FPM_SOFT_RESET); ISP_WRITE(isp, BIU2100_CSR, BIU2100_FB_REGS); ISP_WRITE(isp, FBM_CMD, FBMCMD_FIFO_RESET_ALL); ISP_WRITE(isp, BIU2100_CSR, BIU2100_RISC_REGS); } } } cleanup: isp->isp_nactive = 0; isp_clear_commands(isp); if (IS_FC(isp)) { for (i = 0; i < isp->isp_nchan; i++) { ISP_MARK_PORTDB(isp, i, -1); } } } /* * NVRAM Routines */ static int isp_read_nvram(ispsoftc_t *isp, int bus) { int i, amt, retval; uint8_t csum, minversion; union { uint8_t _x[ISP2400_NVRAM_SIZE]; uint16_t _s[ISP2400_NVRAM_SIZE>>1]; } _n; #define nvram_data _n._x #define nvram_words _n._s if (IS_24XX(isp)) { return (isp_read_nvram_2400(isp, nvram_data)); } else if (IS_FC(isp)) { amt = ISP2100_NVRAM_SIZE; minversion = 1; } else if (IS_ULTRA2(isp)) { amt = ISP1080_NVRAM_SIZE; minversion = 0; } else { amt = ISP_NVRAM_SIZE; minversion = 2; } for (i = 0; i < amt>>1; i++) { isp_rdnvram_word(isp, i, &nvram_words[i]); } if (nvram_data[0] != 'I' || nvram_data[1] != 'S' || nvram_data[2] != 'P') { if (isp->isp_bustype != ISP_BT_SBUS) { isp_prt(isp, ISP_LOGWARN, "invalid NVRAM header"); isp_prt(isp, ISP_LOGDEBUG0, "%x %x %x", nvram_data[0], nvram_data[1], nvram_data[2]); } retval = -1; goto out; } for (csum = 0, i = 0; i < amt; i++) { csum += nvram_data[i]; } if (csum != 0) { isp_prt(isp, ISP_LOGWARN, "invalid NVRAM checksum"); retval = -1; goto out; } if (ISP_NVRAM_VERSION(nvram_data) < minversion) { isp_prt(isp, ISP_LOGWARN, "version %d NVRAM not understood", ISP_NVRAM_VERSION(nvram_data)); retval = -1; goto out; } if (IS_ULTRA3(isp)) { isp_parse_nvram_12160(isp, bus, nvram_data); } else if (IS_1080(isp)) { isp_parse_nvram_1080(isp, bus, nvram_data); } else if (IS_1280(isp) || IS_1240(isp)) { isp_parse_nvram_1080(isp, bus, nvram_data); } else if (IS_SCSI(isp)) { isp_parse_nvram_1020(isp, nvram_data); } else { isp_parse_nvram_2100(isp, nvram_data); } retval = 0; out: return (retval); #undef nvram_data #undef nvram_words } static int isp_read_nvram_2400(ispsoftc_t *isp, uint8_t *nvram_data) { int retval = 0; uint32_t addr, csum, lwrds, *dptr; if (isp->isp_port) { addr = ISP2400_NVRAM_PORT1_ADDR; } else { addr = ISP2400_NVRAM_PORT0_ADDR; } dptr = (uint32_t *) nvram_data; for (lwrds = 0; lwrds < ISP2400_NVRAM_SIZE >> 2; lwrds++) { isp_rd_2400_nvram(isp, addr++, dptr++); } if (nvram_data[0] != 'I' || nvram_data[1] != 'S' || nvram_data[2] != 'P') { isp_prt(isp, ISP_LOGWARN, "invalid NVRAM header (%x %x %x)", nvram_data[0], nvram_data[1], nvram_data[2]); retval = -1; goto out; } dptr = (uint32_t *) nvram_data; for (csum = 0, lwrds = 0; lwrds < ISP2400_NVRAM_SIZE >> 2; lwrds++) { uint32_t tmp; ISP_IOXGET_32(isp, &dptr[lwrds], tmp); csum += tmp; } if (csum != 0) { isp_prt(isp, ISP_LOGWARN, "invalid NVRAM checksum"); retval = -1; goto out; } isp_parse_nvram_2400(isp, nvram_data); out: return (retval); } static void isp_rdnvram_word(ispsoftc_t *isp, int wo, uint16_t *rp) { int i, cbits; uint16_t bit, rqst, junk; ISP_WRITE(isp, BIU_NVRAM, BIU_NVRAM_SELECT); ISP_DELAY(10); ISP_WRITE(isp, BIU_NVRAM, BIU_NVRAM_SELECT|BIU_NVRAM_CLOCK); ISP_DELAY(10); if (IS_FC(isp)) { wo &= ((ISP2100_NVRAM_SIZE >> 1) - 1); if (IS_2312(isp) && isp->isp_port) { wo += 128; } rqst = (ISP_NVRAM_READ << 8) | wo; cbits = 10; } else if (IS_ULTRA2(isp)) { wo &= ((ISP1080_NVRAM_SIZE >> 1) - 1); rqst = (ISP_NVRAM_READ << 8) | wo; cbits = 10; } else { wo &= ((ISP_NVRAM_SIZE >> 1) - 1); rqst = (ISP_NVRAM_READ << 6) | wo; cbits = 8; } /* * Clock the word select request out... */ for (i = cbits; i >= 0; i--) { if ((rqst >> i) & 1) { bit = BIU_NVRAM_SELECT | BIU_NVRAM_DATAOUT; } else { bit = BIU_NVRAM_SELECT; } ISP_WRITE(isp, BIU_NVRAM, bit); ISP_DELAY(10); junk = ISP_READ(isp, BIU_NVRAM); /* force PCI flush */ ISP_WRITE(isp, BIU_NVRAM, bit | BIU_NVRAM_CLOCK); ISP_DELAY(10); junk = ISP_READ(isp, BIU_NVRAM); /* force PCI flush */ ISP_WRITE(isp, BIU_NVRAM, bit); ISP_DELAY(10); junk = ISP_READ(isp, BIU_NVRAM); /* force PCI flush */ } /* * Now read the result back in (bits come back in MSB format). */ *rp = 0; for (i = 0; i < 16; i++) { uint16_t rv; *rp <<= 1; ISP_WRITE(isp, BIU_NVRAM, BIU_NVRAM_SELECT|BIU_NVRAM_CLOCK); ISP_DELAY(10); rv = ISP_READ(isp, BIU_NVRAM); if (rv & BIU_NVRAM_DATAIN) { *rp |= 1; } ISP_DELAY(10); ISP_WRITE(isp, BIU_NVRAM, BIU_NVRAM_SELECT); ISP_DELAY(10); junk = ISP_READ(isp, BIU_NVRAM); /* force PCI flush */ } ISP_WRITE(isp, BIU_NVRAM, 0); ISP_DELAY(10); junk = ISP_READ(isp, BIU_NVRAM); /* force PCI flush */ ISP_SWIZZLE_NVRAM_WORD(isp, rp); } static void isp_rd_2400_nvram(ispsoftc_t *isp, uint32_t addr, uint32_t *rp) { int loops = 0; uint32_t base = 0x7ffe0000; uint32_t tmp = 0; if (IS_25XX(isp)) { base = 0x7ff00000 | 0x48000; } ISP_WRITE(isp, BIU2400_FLASH_ADDR, base | addr); for (loops = 0; loops < 5000; loops++) { ISP_DELAY(10); tmp = ISP_READ(isp, BIU2400_FLASH_ADDR); if ((tmp & (1U << 31)) != 0) { break; } } if (tmp & (1U << 31)) { *rp = ISP_READ(isp, BIU2400_FLASH_DATA); ISP_SWIZZLE_NVRAM_LONG(isp, rp); } else { *rp = 0xffffffff; } } static void isp_parse_nvram_1020(ispsoftc_t *isp, uint8_t *nvram_data) { sdparam *sdp = SDPARAM(isp, 0); int tgt; sdp->isp_fifo_threshold = ISP_NVRAM_FIFO_THRESHOLD(nvram_data) | (ISP_NVRAM_FIFO_THRESHOLD_128(nvram_data) << 2); if ((isp->isp_confopts & ISP_CFG_OWNLOOPID) == 0) sdp->isp_initiator_id = ISP_NVRAM_INITIATOR_ID(nvram_data); sdp->isp_bus_reset_delay = ISP_NVRAM_BUS_RESET_DELAY(nvram_data); sdp->isp_retry_count = ISP_NVRAM_BUS_RETRY_COUNT(nvram_data); sdp->isp_retry_delay = ISP_NVRAM_BUS_RETRY_DELAY(nvram_data); sdp->isp_async_data_setup = ISP_NVRAM_ASYNC_DATA_SETUP_TIME(nvram_data); if (isp->isp_type >= ISP_HA_SCSI_1040) { if (sdp->isp_async_data_setup < 9) { sdp->isp_async_data_setup = 9; } } else { if (sdp->isp_async_data_setup != 6) { sdp->isp_async_data_setup = 6; } } sdp->isp_req_ack_active_neg = ISP_NVRAM_REQ_ACK_ACTIVE_NEGATION(nvram_data); sdp->isp_data_line_active_neg = ISP_NVRAM_DATA_LINE_ACTIVE_NEGATION(nvram_data); sdp->isp_data_dma_burst_enabl = ISP_NVRAM_DATA_DMA_BURST_ENABLE(nvram_data); sdp->isp_cmd_dma_burst_enable = ISP_NVRAM_CMD_DMA_BURST_ENABLE(nvram_data); sdp->isp_tag_aging = ISP_NVRAM_TAG_AGE_LIMIT(nvram_data); sdp->isp_selection_timeout = ISP_NVRAM_SELECTION_TIMEOUT(nvram_data); sdp->isp_max_queue_depth = ISP_NVRAM_MAX_QUEUE_DEPTH(nvram_data); sdp->isp_fast_mttr = ISP_NVRAM_FAST_MTTR_ENABLE(nvram_data); for (tgt = 0; tgt < MAX_TARGETS; tgt++) { sdp->isp_devparam[tgt].dev_enable = ISP_NVRAM_TGT_DEVICE_ENABLE(nvram_data, tgt); sdp->isp_devparam[tgt].exc_throttle = ISP_NVRAM_TGT_EXEC_THROTTLE(nvram_data, tgt); sdp->isp_devparam[tgt].nvrm_offset = ISP_NVRAM_TGT_SYNC_OFFSET(nvram_data, tgt); sdp->isp_devparam[tgt].nvrm_period = ISP_NVRAM_TGT_SYNC_PERIOD(nvram_data, tgt); /* * We probably shouldn't lie about this, but it * it makes it much safer if we limit NVRAM values * to sanity. */ if (isp->isp_type < ISP_HA_SCSI_1040) { /* * If we're not ultra, we can't possibly * be a shorter period than this. */ if (sdp->isp_devparam[tgt].nvrm_period < 0x19) { sdp->isp_devparam[tgt].nvrm_period = 0x19; } if (sdp->isp_devparam[tgt].nvrm_offset > 0xc) { sdp->isp_devparam[tgt].nvrm_offset = 0x0c; } } else { if (sdp->isp_devparam[tgt].nvrm_offset > 0x8) { sdp->isp_devparam[tgt].nvrm_offset = 0x8; } } sdp->isp_devparam[tgt].nvrm_flags = 0; if (ISP_NVRAM_TGT_RENEG(nvram_data, tgt)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_RENEG; sdp->isp_devparam[tgt].nvrm_flags |= DPARM_ARQ; if (ISP_NVRAM_TGT_TQING(nvram_data, tgt)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_TQING; if (ISP_NVRAM_TGT_SYNC(nvram_data, tgt)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_SYNC; if (ISP_NVRAM_TGT_WIDE(nvram_data, tgt)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_WIDE; if (ISP_NVRAM_TGT_PARITY(nvram_data, tgt)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_PARITY; if (ISP_NVRAM_TGT_DISC(nvram_data, tgt)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_DISC; sdp->isp_devparam[tgt].actv_flags = 0; /* we don't know */ sdp->isp_devparam[tgt].goal_offset = sdp->isp_devparam[tgt].nvrm_offset; sdp->isp_devparam[tgt].goal_period = sdp->isp_devparam[tgt].nvrm_period; sdp->isp_devparam[tgt].goal_flags = sdp->isp_devparam[tgt].nvrm_flags; } } static void isp_parse_nvram_1080(ispsoftc_t *isp, int bus, uint8_t *nvram_data) { sdparam *sdp = SDPARAM(isp, bus); int tgt; sdp->isp_fifo_threshold = ISP1080_NVRAM_FIFO_THRESHOLD(nvram_data); if ((isp->isp_confopts & ISP_CFG_OWNLOOPID) == 0) sdp->isp_initiator_id = ISP1080_NVRAM_INITIATOR_ID(nvram_data, bus); sdp->isp_bus_reset_delay = ISP1080_NVRAM_BUS_RESET_DELAY(nvram_data, bus); sdp->isp_retry_count = ISP1080_NVRAM_BUS_RETRY_COUNT(nvram_data, bus); sdp->isp_retry_delay = ISP1080_NVRAM_BUS_RETRY_DELAY(nvram_data, bus); sdp->isp_async_data_setup = ISP1080_NVRAM_ASYNC_DATA_SETUP_TIME(nvram_data, bus); sdp->isp_req_ack_active_neg = ISP1080_NVRAM_REQ_ACK_ACTIVE_NEGATION(nvram_data, bus); sdp->isp_data_line_active_neg = ISP1080_NVRAM_DATA_LINE_ACTIVE_NEGATION(nvram_data, bus); sdp->isp_data_dma_burst_enabl = ISP1080_NVRAM_BURST_ENABLE(nvram_data); sdp->isp_cmd_dma_burst_enable = ISP1080_NVRAM_BURST_ENABLE(nvram_data); sdp->isp_selection_timeout = ISP1080_NVRAM_SELECTION_TIMEOUT(nvram_data, bus); sdp->isp_max_queue_depth = ISP1080_NVRAM_MAX_QUEUE_DEPTH(nvram_data, bus); for (tgt = 0; tgt < MAX_TARGETS; tgt++) { sdp->isp_devparam[tgt].dev_enable = ISP1080_NVRAM_TGT_DEVICE_ENABLE(nvram_data, tgt, bus); sdp->isp_devparam[tgt].exc_throttle = ISP1080_NVRAM_TGT_EXEC_THROTTLE(nvram_data, tgt, bus); sdp->isp_devparam[tgt].nvrm_offset = ISP1080_NVRAM_TGT_SYNC_OFFSET(nvram_data, tgt, bus); sdp->isp_devparam[tgt].nvrm_period = ISP1080_NVRAM_TGT_SYNC_PERIOD(nvram_data, tgt, bus); sdp->isp_devparam[tgt].nvrm_flags = 0; if (ISP1080_NVRAM_TGT_RENEG(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_RENEG; sdp->isp_devparam[tgt].nvrm_flags |= DPARM_ARQ; if (ISP1080_NVRAM_TGT_TQING(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_TQING; if (ISP1080_NVRAM_TGT_SYNC(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_SYNC; if (ISP1080_NVRAM_TGT_WIDE(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_WIDE; if (ISP1080_NVRAM_TGT_PARITY(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_PARITY; if (ISP1080_NVRAM_TGT_DISC(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_DISC; sdp->isp_devparam[tgt].actv_flags = 0; sdp->isp_devparam[tgt].goal_offset = sdp->isp_devparam[tgt].nvrm_offset; sdp->isp_devparam[tgt].goal_period = sdp->isp_devparam[tgt].nvrm_period; sdp->isp_devparam[tgt].goal_flags = sdp->isp_devparam[tgt].nvrm_flags; } } static void isp_parse_nvram_12160(ispsoftc_t *isp, int bus, uint8_t *nvram_data) { sdparam *sdp = SDPARAM(isp, bus); int tgt; sdp->isp_fifo_threshold = ISP12160_NVRAM_FIFO_THRESHOLD(nvram_data); if ((isp->isp_confopts & ISP_CFG_OWNLOOPID) == 0) sdp->isp_initiator_id = ISP12160_NVRAM_INITIATOR_ID(nvram_data, bus); sdp->isp_bus_reset_delay = ISP12160_NVRAM_BUS_RESET_DELAY(nvram_data, bus); sdp->isp_retry_count = ISP12160_NVRAM_BUS_RETRY_COUNT(nvram_data, bus); sdp->isp_retry_delay = ISP12160_NVRAM_BUS_RETRY_DELAY(nvram_data, bus); sdp->isp_async_data_setup = ISP12160_NVRAM_ASYNC_DATA_SETUP_TIME(nvram_data, bus); sdp->isp_req_ack_active_neg = ISP12160_NVRAM_REQ_ACK_ACTIVE_NEGATION(nvram_data, bus); sdp->isp_data_line_active_neg = ISP12160_NVRAM_DATA_LINE_ACTIVE_NEGATION(nvram_data, bus); sdp->isp_data_dma_burst_enabl = ISP12160_NVRAM_BURST_ENABLE(nvram_data); sdp->isp_cmd_dma_burst_enable = ISP12160_NVRAM_BURST_ENABLE(nvram_data); sdp->isp_selection_timeout = ISP12160_NVRAM_SELECTION_TIMEOUT(nvram_data, bus); sdp->isp_max_queue_depth = ISP12160_NVRAM_MAX_QUEUE_DEPTH(nvram_data, bus); for (tgt = 0; tgt < MAX_TARGETS; tgt++) { sdp->isp_devparam[tgt].dev_enable = ISP12160_NVRAM_TGT_DEVICE_ENABLE(nvram_data, tgt, bus); sdp->isp_devparam[tgt].exc_throttle = ISP12160_NVRAM_TGT_EXEC_THROTTLE(nvram_data, tgt, bus); sdp->isp_devparam[tgt].nvrm_offset = ISP12160_NVRAM_TGT_SYNC_OFFSET(nvram_data, tgt, bus); sdp->isp_devparam[tgt].nvrm_period = ISP12160_NVRAM_TGT_SYNC_PERIOD(nvram_data, tgt, bus); sdp->isp_devparam[tgt].nvrm_flags = 0; if (ISP12160_NVRAM_TGT_RENEG(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_RENEG; sdp->isp_devparam[tgt].nvrm_flags |= DPARM_ARQ; if (ISP12160_NVRAM_TGT_TQING(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_TQING; if (ISP12160_NVRAM_TGT_SYNC(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_SYNC; if (ISP12160_NVRAM_TGT_WIDE(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_WIDE; if (ISP12160_NVRAM_TGT_PARITY(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_PARITY; if (ISP12160_NVRAM_TGT_DISC(nvram_data, tgt, bus)) sdp->isp_devparam[tgt].nvrm_flags |= DPARM_DISC; sdp->isp_devparam[tgt].actv_flags = 0; sdp->isp_devparam[tgt].goal_offset = sdp->isp_devparam[tgt].nvrm_offset; sdp->isp_devparam[tgt].goal_period = sdp->isp_devparam[tgt].nvrm_period; sdp->isp_devparam[tgt].goal_flags = sdp->isp_devparam[tgt].nvrm_flags; } } static void isp_parse_nvram_2100(ispsoftc_t *isp, uint8_t *nvram_data) { fcparam *fcp = FCPARAM(isp, 0); uint64_t wwn; /* * There is NVRAM storage for both Port and Node entities- * but the Node entity appears to be unused on all the cards * I can find. However, we should account for this being set * at some point in the future. * * Qlogic WWNs have an NAA of 2, but usually nothing shows up in * bits 48..60. In the case of the 2202, it appears that they do * use bit 48 to distinguish between the two instances on the card. * The 2204, which I've never seen, *probably* extends this method. */ wwn = ISP2100_NVRAM_PORT_NAME(nvram_data); if (wwn) { isp_prt(isp, ISP_LOGCONFIG, "NVRAM Port WWN 0x%08x%08x", (uint32_t) (wwn >> 32), (uint32_t) (wwn)); if ((wwn >> 60) == 0) { wwn |= (((uint64_t) 2)<< 60); } } fcp->isp_wwpn_nvram = wwn; if (IS_2200(isp) || IS_23XX(isp)) { wwn = ISP2100_NVRAM_NODE_NAME(nvram_data); if (wwn) { isp_prt(isp, ISP_LOGCONFIG, "NVRAM Node WWN 0x%08x%08x", (uint32_t) (wwn >> 32), (uint32_t) (wwn)); if ((wwn >> 60) == 0) { wwn |= (((uint64_t) 2)<< 60); } } else { wwn = fcp->isp_wwpn_nvram & ~((uint64_t) 0xfff << 48); } } else { wwn &= ~((uint64_t) 0xfff << 48); } fcp->isp_wwnn_nvram = wwn; fcp->isp_maxalloc = ISP2100_NVRAM_MAXIOCBALLOCATION(nvram_data); if ((isp->isp_confopts & ISP_CFG_OWNFSZ) == 0) { DEFAULT_FRAMESIZE(isp) = ISP2100_NVRAM_MAXFRAMELENGTH(nvram_data); } fcp->isp_retry_delay = ISP2100_NVRAM_RETRY_DELAY(nvram_data); fcp->isp_retry_count = ISP2100_NVRAM_RETRY_COUNT(nvram_data); if ((isp->isp_confopts & ISP_CFG_OWNLOOPID) == 0) { fcp->isp_loopid = ISP2100_NVRAM_HARDLOOPID(nvram_data); } if ((isp->isp_confopts & ISP_CFG_OWNEXCTHROTTLE) == 0) { DEFAULT_EXEC_THROTTLE(isp) = ISP2100_NVRAM_EXECUTION_THROTTLE(nvram_data); } fcp->isp_fwoptions = ISP2100_NVRAM_OPTIONS(nvram_data); isp_prt(isp, ISP_LOGDEBUG0, "NVRAM 0x%08x%08x 0x%08x%08x maxalloc %d maxframelen %d", (uint32_t) (fcp->isp_wwnn_nvram >> 32), (uint32_t) fcp->isp_wwnn_nvram, (uint32_t) (fcp->isp_wwpn_nvram >> 32), (uint32_t) fcp->isp_wwpn_nvram, ISP2100_NVRAM_MAXIOCBALLOCATION(nvram_data), ISP2100_NVRAM_MAXFRAMELENGTH(nvram_data)); isp_prt(isp, ISP_LOGDEBUG0, "execthrottle %d fwoptions 0x%x hardloop %d tov %d", ISP2100_NVRAM_EXECUTION_THROTTLE(nvram_data), ISP2100_NVRAM_OPTIONS(nvram_data), ISP2100_NVRAM_HARDLOOPID(nvram_data), ISP2100_NVRAM_TOV(nvram_data)); fcp->isp_xfwoptions = ISP2100_XFW_OPTIONS(nvram_data); fcp->isp_zfwoptions = ISP2100_ZFW_OPTIONS(nvram_data); isp_prt(isp, ISP_LOGDEBUG0, "xfwoptions 0x%x zfw options 0x%x", ISP2100_XFW_OPTIONS(nvram_data), ISP2100_ZFW_OPTIONS(nvram_data)); } static void isp_parse_nvram_2400(ispsoftc_t *isp, uint8_t *nvram_data) { fcparam *fcp = FCPARAM(isp, 0); uint64_t wwn; isp_prt(isp, ISP_LOGDEBUG0, "NVRAM 0x%08x%08x 0x%08x%08x exchg_cnt %d maxframelen %d", (uint32_t) (ISP2400_NVRAM_NODE_NAME(nvram_data) >> 32), (uint32_t) (ISP2400_NVRAM_NODE_NAME(nvram_data)), (uint32_t) (ISP2400_NVRAM_PORT_NAME(nvram_data) >> 32), (uint32_t) (ISP2400_NVRAM_PORT_NAME(nvram_data)), ISP2400_NVRAM_EXCHANGE_COUNT(nvram_data), ISP2400_NVRAM_MAXFRAMELENGTH(nvram_data)); isp_prt(isp, ISP_LOGDEBUG0, "NVRAM execthr %d loopid %d fwopt1 0x%x fwopt2 0x%x fwopt3 0x%x", ISP2400_NVRAM_EXECUTION_THROTTLE(nvram_data), ISP2400_NVRAM_HARDLOOPID(nvram_data), ISP2400_NVRAM_FIRMWARE_OPTIONS1(nvram_data), ISP2400_NVRAM_FIRMWARE_OPTIONS2(nvram_data), ISP2400_NVRAM_FIRMWARE_OPTIONS3(nvram_data)); wwn = ISP2400_NVRAM_PORT_NAME(nvram_data); fcp->isp_wwpn_nvram = wwn; wwn = ISP2400_NVRAM_NODE_NAME(nvram_data); if (wwn) { if ((wwn >> 60) != 2 && (wwn >> 60) != 5) { wwn = 0; } } if (wwn == 0 && (fcp->isp_wwpn_nvram >> 60) == 2) { wwn = fcp->isp_wwpn_nvram; wwn &= ~((uint64_t) 0xfff << 48); } fcp->isp_wwnn_nvram = wwn; if (ISP2400_NVRAM_EXCHANGE_COUNT(nvram_data)) { fcp->isp_maxalloc = ISP2400_NVRAM_EXCHANGE_COUNT(nvram_data); } if ((isp->isp_confopts & ISP_CFG_OWNFSZ) == 0) { DEFAULT_FRAMESIZE(isp) = ISP2400_NVRAM_MAXFRAMELENGTH(nvram_data); } if ((isp->isp_confopts & ISP_CFG_OWNLOOPID) == 0) { fcp->isp_loopid = ISP2400_NVRAM_HARDLOOPID(nvram_data); } if ((isp->isp_confopts & ISP_CFG_OWNEXCTHROTTLE) == 0) { DEFAULT_EXEC_THROTTLE(isp) = ISP2400_NVRAM_EXECUTION_THROTTLE(nvram_data); } fcp->isp_fwoptions = ISP2400_NVRAM_FIRMWARE_OPTIONS1(nvram_data); fcp->isp_xfwoptions = ISP2400_NVRAM_FIRMWARE_OPTIONS2(nvram_data); fcp->isp_zfwoptions = ISP2400_NVRAM_FIRMWARE_OPTIONS3(nvram_data); } Index: stable/9/sys/dev/isp/isp_freebsd.c =================================================================== --- stable/9/sys/dev/isp/isp_freebsd.c (revision 237207) +++ stable/9/sys/dev/isp/isp_freebsd.c (revision 237208) @@ -1,5730 +1,5805 @@ /*- * Copyright (c) 1997-2009 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. * 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. */ /* * Platform (FreeBSD) dependent common attachment code for Qlogic adapters. */ #include __FBSDID("$FreeBSD$"); #include #include #include #include #include #include #include #include #include #include #if __FreeBSD_version < 800002 #define THREAD_CREATE kthread_create #else #define THREAD_CREATE kproc_create #endif MODULE_VERSION(isp, 1); MODULE_DEPEND(isp, cam, 1, 1, 1); int isp_announced = 0; int isp_fabric_hysteresis = 5; int isp_loop_down_limit = 60; /* default loop down limit */ int isp_change_is_bad = 0; /* "changed" devices are bad */ int isp_quickboot_time = 7; /* don't wait more than N secs for loop up */ int isp_gone_device_time = 30; /* grace time before reporting device lost */ int isp_autoconfig = 1; /* automatically attach/detach devices */ static const char *roles[4] = { "(none)", "Target", "Initiator", "Target/Initiator" }; static const char prom3[] = "Chan %d PortID 0x%06x Departed from Target %u because of %s"; static const char rqo[] = "%s: Request Queue Overflow\n"; static void isp_freeze_loopdown(ispsoftc_t *, int, char *); static d_ioctl_t ispioctl; static void isp_intr_enable(void *); static void isp_cam_async(void *, uint32_t, struct cam_path *, void *); static void isp_poll(struct cam_sim *); static timeout_t isp_watchdog; static timeout_t isp_gdt; static task_fn_t isp_gdt_task; static timeout_t isp_ldt; static task_fn_t isp_ldt_task; static void isp_kthread(void *); static void isp_action(struct cam_sim *, union ccb *); #ifdef ISP_INTERNAL_TARGET static void isp_target_thread_pi(void *); static void isp_target_thread_fc(void *); #endif static void isp_timer(void *); static struct cdevsw isp_cdevsw = { .d_version = D_VERSION, .d_ioctl = ispioctl, .d_name = "isp", }; static int isp_attach_chan(ispsoftc_t *isp, struct cam_devq *devq, int chan) { struct ccb_setasync csa; struct cam_sim *sim; struct cam_path *path; /* * Construct our SIM entry. */ sim = cam_sim_alloc(isp_action, isp_poll, "isp", isp, device_get_unit(isp->isp_dev), &isp->isp_osinfo.lock, isp->isp_maxcmds, isp->isp_maxcmds, devq); if (sim == NULL) { return (ENOMEM); } ISP_LOCK(isp); if (xpt_bus_register(sim, isp->isp_dev, chan) != CAM_SUCCESS) { ISP_UNLOCK(isp); cam_sim_free(sim, FALSE); return (EIO); } ISP_UNLOCK(isp); if (xpt_create_path_unlocked(&path, NULL, cam_sim_path(sim), CAM_TARGET_WILDCARD, CAM_LUN_WILDCARD) != CAM_REQ_CMP) { ISP_LOCK(isp); xpt_bus_deregister(cam_sim_path(sim)); ISP_UNLOCK(isp); cam_sim_free(sim, FALSE); return (ENXIO); } xpt_setup_ccb(&csa.ccb_h, path, 5); csa.ccb_h.func_code = XPT_SASYNC_CB; csa.event_enable = AC_LOST_DEVICE; csa.callback = isp_cam_async; csa.callback_arg = sim; xpt_action((union ccb *)&csa); if (IS_SCSI(isp)) { struct isp_spi *spi = ISP_SPI_PC(isp, chan); spi->sim = sim; spi->path = path; #ifdef ISP_INTERNAL_TARGET ISP_SET_PC(isp, chan, proc_active, 1); if (THREAD_CREATE(isp_target_thread_pi, spi, &spi->target_proc, 0, 0, "%s: isp_test_tgt%d", device_get_nameunit(isp->isp_osinfo.dev), chan)) { ISP_SET_PC(isp, chan, proc_active, 0); isp_prt(isp, ISP_LOGERR, "cannot create test target thread"); } #endif } else { fcparam *fcp = FCPARAM(isp, chan); struct isp_fc *fc = ISP_FC_PC(isp, chan); ISP_LOCK(isp); fc->sim = sim; fc->path = path; fc->isp = isp; fc->ready = 1; callout_init_mtx(&fc->ldt, &isp->isp_osinfo.lock, 0); callout_init_mtx(&fc->gdt, &isp->isp_osinfo.lock, 0); TASK_INIT(&fc->ltask, 1, isp_ldt_task, fc); TASK_INIT(&fc->gtask, 1, isp_gdt_task, fc); /* * We start by being "loop down" if we have an initiator role */ if (fcp->role & ISP_ROLE_INITIATOR) { isp_freeze_loopdown(isp, chan, "isp_attach"); callout_reset(&fc->ldt, isp_quickboot_time * hz, isp_ldt, fc); isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Starting Initial Loop Down Timer @ %lu", (unsigned long) time_uptime); } ISP_UNLOCK(isp); if (THREAD_CREATE(isp_kthread, fc, &fc->kproc, 0, 0, "%s: fc_thrd%d", device_get_nameunit(isp->isp_osinfo.dev), chan)) { xpt_free_path(fc->path); ISP_LOCK(isp); if (callout_active(&fc->ldt)) { callout_stop(&fc->ldt); } xpt_bus_deregister(cam_sim_path(fc->sim)); ISP_UNLOCK(isp); cam_sim_free(fc->sim, FALSE); return (ENOMEM); } #ifdef ISP_INTERNAL_TARGET ISP_SET_PC(isp, chan, proc_active, 1); if (THREAD_CREATE(isp_target_thread_fc, fc, &fc->target_proc, 0, 0, "%s: isp_test_tgt%d", device_get_nameunit(isp->isp_osinfo.dev), chan)) { ISP_SET_PC(isp, chan, proc_active, 0); isp_prt(isp, ISP_LOGERR, "cannot create test target thread"); } #endif } return (0); } int isp_attach(ispsoftc_t *isp) { const char *nu = device_get_nameunit(isp->isp_osinfo.dev); int du = device_get_unit(isp->isp_dev); int chan; isp->isp_osinfo.ehook.ich_func = isp_intr_enable; isp->isp_osinfo.ehook.ich_arg = isp; /* * Haha. Set this first, because if we're loaded as a module isp_intr_enable * will be called right awawy, which will clear isp_osinfo.ehook_active, * which would be unwise to then set again later. */ isp->isp_osinfo.ehook_active = 1; if (config_intrhook_establish(&isp->isp_osinfo.ehook) != 0) { isp_prt(isp, ISP_LOGERR, "could not establish interrupt enable hook"); return (-EIO); } /* * Create the device queue for our SIM(s). */ isp->isp_osinfo.devq = cam_simq_alloc(isp->isp_maxcmds); if (isp->isp_osinfo.devq == NULL) { config_intrhook_disestablish(&isp->isp_osinfo.ehook); return (EIO); } for (chan = 0; chan < isp->isp_nchan; chan++) { if (isp_attach_chan(isp, isp->isp_osinfo.devq, chan)) { goto unwind; } } callout_init_mtx(&isp->isp_osinfo.tmo, &isp->isp_osinfo.lock, 0); callout_reset(&isp->isp_osinfo.tmo, hz, isp_timer, isp); isp->isp_osinfo.timer_active = 1; isp->isp_osinfo.cdev = make_dev(&isp_cdevsw, du, UID_ROOT, GID_OPERATOR, 0600, "%s", nu); if (isp->isp_osinfo.cdev) { isp->isp_osinfo.cdev->si_drv1 = isp; } return (0); unwind: while (--chan >= 0) { struct cam_sim *sim; struct cam_path *path; if (IS_FC(isp)) { sim = ISP_FC_PC(isp, chan)->sim; path = ISP_FC_PC(isp, chan)->path; } else { sim = ISP_SPI_PC(isp, chan)->sim; path = ISP_SPI_PC(isp, chan)->path; } xpt_free_path(path); ISP_LOCK(isp); xpt_bus_deregister(cam_sim_path(sim)); ISP_UNLOCK(isp); cam_sim_free(sim, FALSE); } if (isp->isp_osinfo.ehook_active) { config_intrhook_disestablish(&isp->isp_osinfo.ehook); isp->isp_osinfo.ehook_active = 0; } if (isp->isp_osinfo.cdev) { destroy_dev(isp->isp_osinfo.cdev); isp->isp_osinfo.cdev = NULL; } cam_simq_free(isp->isp_osinfo.devq); isp->isp_osinfo.devq = NULL; return (-1); } int isp_detach(ispsoftc_t *isp) { struct cam_sim *sim; struct cam_path *path; struct ccb_setasync csa; int chan; ISP_LOCK(isp); for (chan = isp->isp_nchan - 1; chan >= 0; chan -= 1) { if (IS_FC(isp)) { sim = ISP_FC_PC(isp, chan)->sim; path = ISP_FC_PC(isp, chan)->path; } else { sim = ISP_SPI_PC(isp, chan)->sim; path = ISP_SPI_PC(isp, chan)->path; } if (sim->refcount > 2) { ISP_UNLOCK(isp); return (EBUSY); } } if (isp->isp_osinfo.timer_active) { callout_stop(&isp->isp_osinfo.tmo); isp->isp_osinfo.timer_active = 0; } for (chan = isp->isp_nchan - 1; chan >= 0; chan -= 1) { if (IS_FC(isp)) { sim = ISP_FC_PC(isp, chan)->sim; path = ISP_FC_PC(isp, chan)->path; } else { sim = ISP_SPI_PC(isp, chan)->sim; path = ISP_SPI_PC(isp, chan)->path; } xpt_setup_ccb(&csa.ccb_h, path, 5); csa.ccb_h.func_code = XPT_SASYNC_CB; csa.event_enable = 0; csa.callback = isp_cam_async; csa.callback_arg = sim; xpt_action((union ccb *)&csa); xpt_free_path(path); xpt_bus_deregister(cam_sim_path(sim)); cam_sim_free(sim, FALSE); } ISP_UNLOCK(isp); if (isp->isp_osinfo.cdev) { destroy_dev(isp->isp_osinfo.cdev); isp->isp_osinfo.cdev = NULL; } if (isp->isp_osinfo.ehook_active) { config_intrhook_disestablish(&isp->isp_osinfo.ehook); isp->isp_osinfo.ehook_active = 0; } if (isp->isp_osinfo.devq != NULL) { cam_simq_free(isp->isp_osinfo.devq); isp->isp_osinfo.devq = NULL; } return (0); } static void isp_freeze_loopdown(ispsoftc_t *isp, int chan, char *msg) { if (IS_FC(isp)) { struct isp_fc *fc = ISP_FC_PC(isp, chan); if (fc->simqfrozen == 0) { isp_prt(isp, ISP_LOGDEBUG0, "%s: freeze simq (loopdown) chan %d", msg, chan); fc->simqfrozen = SIMQFRZ_LOOPDOWN; xpt_freeze_simq(fc->sim, 1); } else { isp_prt(isp, ISP_LOGDEBUG0, "%s: mark frozen (loopdown) chan %d", msg, chan); fc->simqfrozen |= SIMQFRZ_LOOPDOWN; } } } static void isp_unfreeze_loopdown(ispsoftc_t *isp, int chan) { if (IS_FC(isp)) { struct isp_fc *fc = ISP_FC_PC(isp, chan); int wasfrozen = fc->simqfrozen & SIMQFRZ_LOOPDOWN; fc->simqfrozen &= ~SIMQFRZ_LOOPDOWN; if (wasfrozen && fc->simqfrozen == 0) { isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "%s: Chan %d releasing simq", __func__, chan); xpt_release_simq(fc->sim, 1); } } } static int ispioctl(struct cdev *dev, u_long c, caddr_t addr, int flags, struct thread *td) { ispsoftc_t *isp; int nr, chan, retval = ENOTTY; isp = dev->si_drv1; switch (c) { case ISP_SDBLEV: { int olddblev = isp->isp_dblev; isp->isp_dblev = *(int *)addr; *(int *)addr = olddblev; retval = 0; break; } case ISP_GETROLE: chan = *(int *)addr; if (chan < 0 || chan >= isp->isp_nchan) { retval = -ENXIO; break; } if (IS_FC(isp)) { *(int *)addr = FCPARAM(isp, chan)->role; } else { *(int *)addr = SDPARAM(isp, chan)->role; } retval = 0; break; case ISP_SETROLE: nr = *(int *)addr; chan = nr >> 8; if (chan < 0 || chan >= isp->isp_nchan) { retval = -ENXIO; break; } nr &= 0xff; if (nr & ~(ISP_ROLE_INITIATOR|ISP_ROLE_TARGET)) { retval = EINVAL; break; } if (IS_FC(isp)) { /* * We don't really support dual role at present on FC cards. * * We should, but a bunch of things are currently broken, * so don't allow it. */ if (nr == ISP_ROLE_BOTH) { isp_prt(isp, ISP_LOGERR, "cannot support dual role at present"); retval = EINVAL; break; } *(int *)addr = FCPARAM(isp, chan)->role; #ifdef ISP_INTERNAL_TARGET ISP_LOCK(isp); retval = isp_fc_change_role(isp, chan, nr); ISP_UNLOCK(isp); #else FCPARAM(isp, chan)->role = nr; #endif } else { *(int *)addr = SDPARAM(isp, chan)->role; SDPARAM(isp, chan)->role = nr; } retval = 0; break; case ISP_RESETHBA: ISP_LOCK(isp); #ifdef ISP_TARGET_MODE isp_del_all_wwn_entries(isp, ISP_NOCHAN); #endif isp_reinit(isp, 0); ISP_UNLOCK(isp); retval = 0; break; case ISP_RESCAN: if (IS_FC(isp)) { chan = *(int *)addr; if (chan < 0 || chan >= isp->isp_nchan) { retval = -ENXIO; break; } ISP_LOCK(isp); if (isp_fc_runstate(isp, chan, 5 * 1000000)) { retval = EIO; } else { retval = 0; } ISP_UNLOCK(isp); } break; case ISP_FC_LIP: if (IS_FC(isp)) { chan = *(int *)addr; if (chan < 0 || chan >= isp->isp_nchan) { retval = -ENXIO; break; } ISP_LOCK(isp); if (isp_control(isp, ISPCTL_SEND_LIP, chan)) { retval = EIO; } else { retval = 0; } ISP_UNLOCK(isp); } break; case ISP_FC_GETDINFO: { struct isp_fc_device *ifc = (struct isp_fc_device *) addr; fcportdb_t *lp; if (IS_SCSI(isp)) { break; } if (ifc->loopid >= MAX_FC_TARG) { retval = EINVAL; break; } lp = &FCPARAM(isp, ifc->chan)->portdb[ifc->loopid]; if (lp->state == FC_PORTDB_STATE_VALID || lp->target_mode) { ifc->role = lp->roles; ifc->loopid = lp->handle; ifc->portid = lp->portid; ifc->node_wwn = lp->node_wwn; ifc->port_wwn = lp->port_wwn; retval = 0; } else { retval = ENODEV; } break; } case ISP_GET_STATS: { isp_stats_t *sp = (isp_stats_t *) addr; ISP_MEMZERO(sp, sizeof (*sp)); sp->isp_stat_version = ISP_STATS_VERSION; sp->isp_type = isp->isp_type; sp->isp_revision = isp->isp_revision; ISP_LOCK(isp); sp->isp_stats[ISP_INTCNT] = isp->isp_intcnt; sp->isp_stats[ISP_INTBOGUS] = isp->isp_intbogus; sp->isp_stats[ISP_INTMBOXC] = isp->isp_intmboxc; sp->isp_stats[ISP_INGOASYNC] = isp->isp_intoasync; sp->isp_stats[ISP_RSLTCCMPLT] = isp->isp_rsltccmplt; sp->isp_stats[ISP_FPHCCMCPLT] = isp->isp_fphccmplt; sp->isp_stats[ISP_RSCCHIWAT] = isp->isp_rscchiwater; sp->isp_stats[ISP_FPCCHIWAT] = isp->isp_fpcchiwater; ISP_UNLOCK(isp); retval = 0; break; } case ISP_CLR_STATS: ISP_LOCK(isp); isp->isp_intcnt = 0; isp->isp_intbogus = 0; isp->isp_intmboxc = 0; isp->isp_intoasync = 0; isp->isp_rsltccmplt = 0; isp->isp_fphccmplt = 0; isp->isp_rscchiwater = 0; isp->isp_fpcchiwater = 0; ISP_UNLOCK(isp); retval = 0; break; case ISP_FC_GETHINFO: { struct isp_hba_device *hba = (struct isp_hba_device *) addr; int chan = hba->fc_channel; if (chan < 0 || chan >= isp->isp_nchan) { retval = ENXIO; break; } hba->fc_fw_major = ISP_FW_MAJORX(isp->isp_fwrev); hba->fc_fw_minor = ISP_FW_MINORX(isp->isp_fwrev); hba->fc_fw_micro = ISP_FW_MICROX(isp->isp_fwrev); hba->fc_nchannels = isp->isp_nchan; if (IS_FC(isp)) { hba->fc_nports = MAX_FC_TARG; hba->fc_speed = FCPARAM(isp, hba->fc_channel)->isp_gbspeed; hba->fc_topology = FCPARAM(isp, chan)->isp_topo + 1; hba->fc_loopid = FCPARAM(isp, chan)->isp_loopid; hba->nvram_node_wwn = FCPARAM(isp, chan)->isp_wwnn_nvram; hba->nvram_port_wwn = FCPARAM(isp, chan)->isp_wwpn_nvram; hba->active_node_wwn = FCPARAM(isp, chan)->isp_wwnn; hba->active_port_wwn = FCPARAM(isp, chan)->isp_wwpn; } else { hba->fc_nports = MAX_TARGETS; hba->fc_speed = 0; hba->fc_topology = 0; hba->nvram_node_wwn = 0ull; hba->nvram_port_wwn = 0ull; hba->active_node_wwn = 0ull; hba->active_port_wwn = 0ull; } retval = 0; break; } case ISP_TSK_MGMT: { int needmarker; struct isp_fc_tsk_mgmt *fct = (struct isp_fc_tsk_mgmt *) addr; uint16_t loopid; mbreg_t mbs; if (IS_SCSI(isp)) { break; } chan = fct->chan; if (chan < 0 || chan >= isp->isp_nchan) { retval = -ENXIO; break; } needmarker = retval = 0; loopid = fct->loopid; ISP_LOCK(isp); if (IS_24XX(isp)) { uint8_t local[QENTRY_LEN]; isp24xx_tmf_t *tmf; isp24xx_statusreq_t *sp; fcparam *fcp = FCPARAM(isp, chan); fcportdb_t *lp; int i; for (i = 0; i < MAX_FC_TARG; i++) { lp = &fcp->portdb[i]; if (lp->handle == loopid) { break; } } if (i == MAX_FC_TARG) { retval = ENXIO; ISP_UNLOCK(isp); break; } /* XXX VALIDATE LP XXX */ tmf = (isp24xx_tmf_t *) local; ISP_MEMZERO(tmf, QENTRY_LEN); tmf->tmf_header.rqs_entry_type = RQSTYPE_TSK_MGMT; tmf->tmf_header.rqs_entry_count = 1; tmf->tmf_nphdl = lp->handle; tmf->tmf_delay = 2; tmf->tmf_timeout = 2; tmf->tmf_tidlo = lp->portid; tmf->tmf_tidhi = lp->portid >> 16; tmf->tmf_vpidx = ISP_GET_VPIDX(isp, chan); tmf->tmf_lun[1] = fct->lun & 0xff; if (fct->lun >= 256) { tmf->tmf_lun[0] = 0x40 | (fct->lun >> 8); } switch (fct->action) { case IPT_CLEAR_ACA: tmf->tmf_flags = ISP24XX_TMF_CLEAR_ACA; break; case IPT_TARGET_RESET: tmf->tmf_flags = ISP24XX_TMF_TARGET_RESET; needmarker = 1; break; case IPT_LUN_RESET: tmf->tmf_flags = ISP24XX_TMF_LUN_RESET; needmarker = 1; break; case IPT_CLEAR_TASK_SET: tmf->tmf_flags = ISP24XX_TMF_CLEAR_TASK_SET; needmarker = 1; break; case IPT_ABORT_TASK_SET: tmf->tmf_flags = ISP24XX_TMF_ABORT_TASK_SET; needmarker = 1; break; default: retval = EINVAL; break; } if (retval) { ISP_UNLOCK(isp); break; } MBSINIT(&mbs, MBOX_EXEC_COMMAND_IOCB_A64, MBLOGALL, 5000000); mbs.param[1] = QENTRY_LEN; mbs.param[2] = DMA_WD1(fcp->isp_scdma); mbs.param[3] = DMA_WD0(fcp->isp_scdma); mbs.param[6] = DMA_WD3(fcp->isp_scdma); mbs.param[7] = DMA_WD2(fcp->isp_scdma); if (FC_SCRATCH_ACQUIRE(isp, chan)) { ISP_UNLOCK(isp); retval = ENOMEM; break; } isp_put_24xx_tmf(isp, tmf, fcp->isp_scratch); MEMORYBARRIER(isp, SYNC_SFORDEV, 0, QENTRY_LEN, chan); sp = (isp24xx_statusreq_t *) local; sp->req_completion_status = 1; retval = isp_control(isp, ISPCTL_RUN_MBOXCMD, &mbs); MEMORYBARRIER(isp, SYNC_SFORCPU, QENTRY_LEN, QENTRY_LEN, chan); isp_get_24xx_response(isp, &((isp24xx_statusreq_t *)fcp->isp_scratch)[1], sp); FC_SCRATCH_RELEASE(isp, chan); if (retval || sp->req_completion_status != 0) { FC_SCRATCH_RELEASE(isp, chan); retval = EIO; } if (retval == 0) { if (needmarker) { fcp->sendmarker = 1; } } } else { MBSINIT(&mbs, 0, MBLOGALL, 0); if (ISP_CAP_2KLOGIN(isp) == 0) { loopid <<= 8; } switch (fct->action) { case IPT_CLEAR_ACA: mbs.param[0] = MBOX_CLEAR_ACA; mbs.param[1] = loopid; mbs.param[2] = fct->lun; break; case IPT_TARGET_RESET: mbs.param[0] = MBOX_TARGET_RESET; mbs.param[1] = loopid; needmarker = 1; break; case IPT_LUN_RESET: mbs.param[0] = MBOX_LUN_RESET; mbs.param[1] = loopid; mbs.param[2] = fct->lun; needmarker = 1; break; case IPT_CLEAR_TASK_SET: mbs.param[0] = MBOX_CLEAR_TASK_SET; mbs.param[1] = loopid; mbs.param[2] = fct->lun; needmarker = 1; break; case IPT_ABORT_TASK_SET: mbs.param[0] = MBOX_ABORT_TASK_SET; mbs.param[1] = loopid; mbs.param[2] = fct->lun; needmarker = 1; break; default: retval = EINVAL; break; } if (retval == 0) { if (needmarker) { FCPARAM(isp, chan)->sendmarker = 1; } retval = isp_control(isp, ISPCTL_RUN_MBOXCMD, &mbs); if (retval) { retval = EIO; } } } ISP_UNLOCK(isp); break; } default: break; } return (retval); } static void isp_intr_enable(void *arg) { int chan; ispsoftc_t *isp = arg; ISP_LOCK(isp); for (chan = 0; chan < isp->isp_nchan; chan++) { if (IS_FC(isp)) { if (FCPARAM(isp, chan)->role != ISP_ROLE_NONE) { ISP_ENABLE_INTS(isp); break; } } else { if (SDPARAM(isp, chan)->role != ISP_ROLE_NONE) { ISP_ENABLE_INTS(isp); break; } } } isp->isp_osinfo.ehook_active = 0; ISP_UNLOCK(isp); /* Release our hook so that the boot can continue. */ config_intrhook_disestablish(&isp->isp_osinfo.ehook); } /* * Local Inlines */ static ISP_INLINE int isp_get_pcmd(ispsoftc_t *, union ccb *); static ISP_INLINE void isp_free_pcmd(ispsoftc_t *, union ccb *); static ISP_INLINE int isp_get_pcmd(ispsoftc_t *isp, union ccb *ccb) { ISP_PCMD(ccb) = isp->isp_osinfo.pcmd_free; if (ISP_PCMD(ccb) == NULL) { return (-1); } isp->isp_osinfo.pcmd_free = ((struct isp_pcmd *)ISP_PCMD(ccb))->next; return (0); } static ISP_INLINE void isp_free_pcmd(ispsoftc_t *isp, union ccb *ccb) { ((struct isp_pcmd *)ISP_PCMD(ccb))->next = isp->isp_osinfo.pcmd_free; isp->isp_osinfo.pcmd_free = ISP_PCMD(ccb); ISP_PCMD(ccb) = NULL; } /* * Put the target mode functions here, because some are inlines */ #ifdef ISP_TARGET_MODE +static ISP_INLINE void isp_tmlock(ispsoftc_t *, const char *); +static ISP_INLINE void isp_tmunlk(ispsoftc_t *); +static ISP_INLINE int is_any_lun_enabled(ispsoftc_t *, int); static ISP_INLINE int is_lun_enabled(ispsoftc_t *, int, lun_id_t); static ISP_INLINE tstate_t *get_lun_statep(ispsoftc_t *, int, lun_id_t); static ISP_INLINE tstate_t *get_lun_statep_from_tag(ispsoftc_t *, int, uint32_t); static ISP_INLINE void rls_lun_statep(ispsoftc_t *, tstate_t *); static ISP_INLINE inot_private_data_t *get_ntp_from_tagdata(ispsoftc_t *, uint32_t, uint32_t, tstate_t **); static ISP_INLINE atio_private_data_t *isp_get_atpd(ispsoftc_t *, tstate_t *, uint32_t); static ISP_INLINE void isp_put_atpd(ispsoftc_t *, tstate_t *, atio_private_data_t *); static ISP_INLINE inot_private_data_t *isp_get_ntpd(ispsoftc_t *, tstate_t *); static ISP_INLINE inot_private_data_t *isp_find_ntpd(ispsoftc_t *, tstate_t *, uint32_t, uint32_t); static ISP_INLINE void isp_put_ntpd(ispsoftc_t *, tstate_t *, inot_private_data_t *); static cam_status create_lun_state(ispsoftc_t *, int, struct cam_path *, tstate_t **); static void destroy_lun_state(ispsoftc_t *, tstate_t *); static void isp_enable_lun(ispsoftc_t *, union ccb *); -static void isp_enable_deferred_luns(ispsoftc_t *, int); +static cam_status isp_enable_deferred_luns(ispsoftc_t *, int); static cam_status isp_enable_deferred(ispsoftc_t *, int, lun_id_t); static void isp_disable_lun(ispsoftc_t *, union ccb *); static int isp_enable_target_mode(ispsoftc_t *, int); +static int isp_disable_target_mode(ispsoftc_t *, int); static void isp_ledone(ispsoftc_t *, lun_entry_t *); static timeout_t isp_refire_putback_atio; static void isp_complete_ctio(union ccb *); static void isp_target_putback_atio(union ccb *); static void isp_target_start_ctio(ispsoftc_t *, union ccb *); static void isp_handle_platform_atio(ispsoftc_t *, at_entry_t *); static void isp_handle_platform_atio2(ispsoftc_t *, at2_entry_t *); static void isp_handle_platform_atio7(ispsoftc_t *, at7_entry_t *); static void isp_handle_platform_ctio(ispsoftc_t *, void *); static void isp_handle_platform_notify_scsi(ispsoftc_t *, in_entry_t *); static void isp_handle_platform_notify_fc(ispsoftc_t *, in_fcentry_t *); static void isp_handle_platform_notify_24xx(ispsoftc_t *, in_fcentry_24xx_t *); static int isp_handle_platform_target_notify_ack(ispsoftc_t *, isp_notify_t *); static void isp_handle_platform_target_tmf(ispsoftc_t *, isp_notify_t *); static void isp_target_mark_aborted(ispsoftc_t *, union ccb *); static void isp_target_mark_aborted_early(ispsoftc_t *, tstate_t *, uint32_t); +static ISP_INLINE void +isp_tmlock(ispsoftc_t *isp, const char *msg) +{ + while (isp->isp_osinfo.tmbusy) { + isp->isp_osinfo.tmwanted = 1; + mtx_sleep(isp, &isp->isp_lock, PRIBIO, msg, 0); + } + isp->isp_osinfo.tmbusy = 1; +} + +static ISP_INLINE void +isp_tmunlk(ispsoftc_t *isp) +{ + isp->isp_osinfo.tmbusy = 0; + if (isp->isp_osinfo.tmwanted) { + isp->isp_osinfo.tmwanted = 0; + wakeup(isp); + } +} + static ISP_INLINE int +is_any_lun_enabled(ispsoftc_t *isp, int bus) +{ + struct tslist *lhp; + int i; + + for (i = 0; i < LUN_HASH_SIZE; i++) { + ISP_GET_PC_ADDR(isp, bus, lun_hash[i], lhp); + if (SLIST_FIRST(lhp)) + return (1); + } + return (0); +} + +static ISP_INLINE int is_lun_enabled(ispsoftc_t *isp, int bus, lun_id_t lun) { tstate_t *tptr; struct tslist *lhp; ISP_GET_PC_ADDR(isp, bus, lun_hash[LUN_HASH_FUNC(lun)], lhp); SLIST_FOREACH(tptr, lhp, next) { if (xpt_path_lun_id(tptr->owner) == lun) { return (1); } } return (0); } static void dump_tstates(ispsoftc_t *isp, int bus) { int i, j; struct tslist *lhp; tstate_t *tptr = NULL; if (bus >= isp->isp_nchan) { return; } for (i = 0; i < LUN_HASH_SIZE; i++) { ISP_GET_PC_ADDR(isp, bus, lun_hash[i], lhp); j = 0; SLIST_FOREACH(tptr, lhp, next) { xpt_print(tptr->owner, "[%d, %d] atio_cnt=%d inot_cnt=%d\n", i, j, tptr->atio_count, tptr->inot_count); j++; } } } static ISP_INLINE tstate_t * get_lun_statep(ispsoftc_t *isp, int bus, lun_id_t lun) { tstate_t *tptr = NULL; struct tslist *lhp; int i; if (bus < isp->isp_nchan) { for (i = 0; i < LUN_HASH_SIZE; i++) { ISP_GET_PC_ADDR(isp, bus, lun_hash[i], lhp); SLIST_FOREACH(tptr, lhp, next) { if (xpt_path_lun_id(tptr->owner) == lun) { tptr->hold++; return (tptr); } } } } return (NULL); } static ISP_INLINE tstate_t * get_lun_statep_from_tag(ispsoftc_t *isp, int bus, uint32_t tagval) { tstate_t *tptr = NULL; atio_private_data_t *atp; struct tslist *lhp; int i; if (bus < isp->isp_nchan && tagval != 0) { for (i = 0; i < LUN_HASH_SIZE; i++) { ISP_GET_PC_ADDR(isp, bus, lun_hash[i], lhp); SLIST_FOREACH(tptr, lhp, next) { atp = isp_get_atpd(isp, tptr, tagval); if (atp && atp->tag == tagval) { tptr->hold++; return (tptr); } } } } return (NULL); } static ISP_INLINE inot_private_data_t * get_ntp_from_tagdata(ispsoftc_t *isp, uint32_t tag_id, uint32_t seq_id, tstate_t **rslt) { inot_private_data_t *ntp; tstate_t *tptr; struct tslist *lhp; int bus, i; for (bus = 0; bus < isp->isp_nchan; bus++) { for (i = 0; i < LUN_HASH_SIZE; i++) { ISP_GET_PC_ADDR(isp, bus, lun_hash[i], lhp); SLIST_FOREACH(tptr, lhp, next) { ntp = isp_find_ntpd(isp, tptr, tag_id, seq_id); if (ntp) { *rslt = tptr; tptr->hold++; return (ntp); } } } } return (NULL); } + static ISP_INLINE void rls_lun_statep(ispsoftc_t *isp, tstate_t *tptr) { KASSERT((tptr->hold), ("tptr not held")); tptr->hold--; } static void isp_tmcmd_restart(ispsoftc_t *isp) { inot_private_data_t *ntp; tstate_t *tptr; struct tslist *lhp; int bus, i; for (bus = 0; bus < isp->isp_nchan; bus++) { for (i = 0; i < LUN_HASH_SIZE; i++) { ISP_GET_PC_ADDR(isp, bus, lun_hash[i], lhp); SLIST_FOREACH(tptr, lhp, next) { inot_private_data_t *restart_queue = tptr->restart_queue; tptr->restart_queue = NULL; while (restart_queue) { ntp = restart_queue; restart_queue = ntp->rd.nt.nt_hba; if (IS_24XX(isp)) { isp_prt(isp, ISP_LOGTDEBUG0, "%s: restarting resrc deprived %x", __func__, ((at7_entry_t *)ntp->rd.data)->at_rxid); isp_handle_platform_atio7(isp, (at7_entry_t *) ntp->rd.data); } else { isp_prt(isp, ISP_LOGTDEBUG0, "%s: restarting resrc deprived %x", __func__, ((at2_entry_t *)ntp->rd.data)->at_rxid); isp_handle_platform_atio2(isp, (at2_entry_t *) ntp->rd.data); } isp_put_ntpd(isp, tptr, ntp); if (tptr->restart_queue && restart_queue != NULL) { ntp = tptr->restart_queue; tptr->restart_queue = restart_queue; while (restart_queue->rd.nt.nt_hba) { restart_queue = restart_queue->rd.nt.nt_hba; } restart_queue->rd.nt.nt_hba = ntp; break; } } } } } } static ISP_INLINE atio_private_data_t * isp_get_atpd(ispsoftc_t *isp, tstate_t *tptr, uint32_t tag) { atio_private_data_t *atp; if (tag == 0) { atp = tptr->atfree; if (atp) { tptr->atfree = atp->next; } return (atp); } for (atp = tptr->atpool; atp < &tptr->atpool[ATPDPSIZE]; atp++) { if (atp->tag == tag) { return (atp); } } return (NULL); } static ISP_INLINE void isp_put_atpd(ispsoftc_t *isp, tstate_t *tptr, atio_private_data_t *atp) { atp->tag = 0; atp->dead = 0; atp->next = tptr->atfree; tptr->atfree = atp; } static void isp_dump_atpd(ispsoftc_t *isp, tstate_t *tptr) { atio_private_data_t *atp; const char *states[8] = { "Free", "ATIO", "CAM", "CTIO", "LAST_CTIO", "PDON", "?6", "7" }; for (atp = tptr->atpool; atp < &tptr->atpool[ATPDPSIZE]; atp++) { if (atp->tag == 0) { continue; } xpt_print(tptr->owner, "ATP: [0x%x] origdlen %u bytes_xfrd %u last_xfr %u lun %u nphdl 0x%04x s_id 0x%06x d_id 0x%06x oxid 0x%04x state %s\n", atp->tag, atp->orig_datalen, atp->bytes_xfered, atp->last_xframt, atp->lun, atp->nphdl, atp->sid, atp->portid, atp->oxid, states[atp->state & 0x7]); } } static ISP_INLINE inot_private_data_t * isp_get_ntpd(ispsoftc_t *isp, tstate_t *tptr) { inot_private_data_t *ntp; ntp = tptr->ntfree; if (ntp) { tptr->ntfree = ntp->next; } return (ntp); } static ISP_INLINE inot_private_data_t * isp_find_ntpd(ispsoftc_t *isp, tstate_t *tptr, uint32_t tag_id, uint32_t seq_id) { inot_private_data_t *ntp; for (ntp = tptr->ntpool; ntp < &tptr->ntpool[ATPDPSIZE]; ntp++) { if (ntp->rd.tag_id == tag_id && ntp->rd.seq_id == seq_id) { return (ntp); } } return (NULL); } static ISP_INLINE void isp_put_ntpd(ispsoftc_t *isp, tstate_t *tptr, inot_private_data_t *ntp) { ntp->rd.tag_id = ntp->rd.seq_id = 0; ntp->next = tptr->ntfree; tptr->ntfree = ntp; } static cam_status create_lun_state(ispsoftc_t *isp, int bus, struct cam_path *path, tstate_t **rslt) { cam_status status; lun_id_t lun; struct tslist *lhp; tstate_t *tptr; int i; lun = xpt_path_lun_id(path); if (lun != CAM_LUN_WILDCARD) { if (lun >= ISP_MAX_LUNS(isp)) { return (CAM_LUN_INVALID); } } if (is_lun_enabled(isp, bus, lun)) { return (CAM_LUN_ALRDY_ENA); } - tptr = (tstate_t *) malloc(sizeof (tstate_t), M_DEVBUF, M_NOWAIT|M_ZERO); + tptr = malloc(sizeof (tstate_t), M_DEVBUF, M_NOWAIT|M_ZERO); if (tptr == NULL) { return (CAM_RESRC_UNAVAIL); } status = xpt_create_path(&tptr->owner, NULL, xpt_path_path_id(path), xpt_path_target_id(path), lun); if (status != CAM_REQ_CMP) { free(tptr, M_DEVBUF); return (status); } SLIST_INIT(&tptr->atios); SLIST_INIT(&tptr->inots); for (i = 0; i < ATPDPSIZE-1; i++) { tptr->atpool[i].next = &tptr->atpool[i+1]; tptr->ntpool[i].next = &tptr->ntpool[i+1]; } tptr->atfree = tptr->atpool; tptr->ntfree = tptr->ntpool; tptr->hold = 1; ISP_GET_PC_ADDR(isp, bus, lun_hash[LUN_HASH_FUNC(xpt_path_lun_id(tptr->owner))], lhp); SLIST_INSERT_HEAD(lhp, tptr, next); *rslt = tptr; ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, path, "created tstate\n"); return (CAM_REQ_CMP); } static ISP_INLINE void destroy_lun_state(ispsoftc_t *isp, tstate_t *tptr) { struct tslist *lhp; + KASSERT((tptr->hold != 0), ("tptr is not held")); KASSERT((tptr->hold == 1), ("tptr still held (%d)", tptr->hold)); ISP_GET_PC_ADDR(isp, cam_sim_bus(xpt_path_sim(tptr->owner)), lun_hash[LUN_HASH_FUNC(xpt_path_lun_id(tptr->owner))], lhp); SLIST_REMOVE(lhp, tptr, tstate, next); + ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, tptr->owner, "destroyed tstate\n"); xpt_free_path(tptr->owner); free(tptr, M_DEVBUF); } /* * Enable a lun. */ static void isp_enable_lun(ispsoftc_t *isp, union ccb *ccb) { tstate_t *tptr = NULL; int bus, tm_enabled, target_role; target_id_t target; lun_id_t lun; + /* * We only support either a wildcard target/lun or a target ID of zero and a non-wildcard lun */ bus = XS_CHANNEL(ccb); target = ccb->ccb_h.target_id; lun = ccb->ccb_h.target_lun; + ISP_PATH_PRT(isp, ISP_LOGTDEBUG0|ISP_LOGCONFIG, ccb->ccb_h.path, "enabling lun %u\n", lun); if (target != CAM_TARGET_WILDCARD && target != 0) { ccb->ccb_h.status = CAM_TID_INVALID; xpt_done(ccb); return; } if (target == CAM_TARGET_WILDCARD && lun != CAM_LUN_WILDCARD) { ccb->ccb_h.status = CAM_LUN_INVALID; xpt_done(ccb); return; } if (target != CAM_TARGET_WILDCARD && lun == CAM_LUN_WILDCARD) { ccb->ccb_h.status = CAM_LUN_INVALID; xpt_done(ccb); return; } if (isp->isp_dblev & ISP_LOGTDEBUG0) { xpt_print(ccb->ccb_h.path, "enabling lun 0x%x on channel %d\n", lun, bus); } /* * Wait until we're not busy with the lun enables subsystem */ - while (isp->isp_osinfo.tmbusy) { - isp->isp_osinfo.tmwanted = 1; - mtx_sleep(isp, &isp->isp_lock, PRIBIO, "want_isp_enable_lun", 0); - } - isp->isp_osinfo.tmbusy = 1; + isp_tmlock(isp, "isp_enable_lun"); /* * This is as a good a place as any to check f/w capabilities. */ if (IS_FC(isp)) { if (ISP_CAP_TMODE(isp) == 0) { xpt_print(ccb->ccb_h.path, "firmware does not support target mode\n"); ccb->ccb_h.status = CAM_FUNC_NOTAVAIL; goto done; } /* * We *could* handle non-SCCLUN f/w, but we'd have to * dork with our already fragile enable/disable code. */ if (ISP_CAP_SCCFW(isp) == 0) { xpt_print(ccb->ccb_h.path, "firmware not SCCLUN capable\n"); ccb->ccb_h.status = CAM_FUNC_NOTAVAIL; goto done; } target_role = (FCPARAM(isp, bus)->role & ISP_ROLE_TARGET) != 0; } else { target_role = (SDPARAM(isp, bus)->role & ISP_ROLE_TARGET) != 0; } /* * Create the state pointer. * It should not already exist. */ tptr = get_lun_statep(isp, bus, lun); if (tptr) { ccb->ccb_h.status = CAM_LUN_ALRDY_ENA; goto done; } ccb->ccb_h.status = create_lun_state(isp, bus, ccb->ccb_h.path, &tptr); if (ccb->ccb_h.status != CAM_REQ_CMP) { goto done; } /* * We have a tricky maneuver to perform here. * * If target mode isn't already enabled here, * *and* our current role includes target mode, * we enable target mode here. * */ ISP_GET_PC(isp, bus, tm_enabled, tm_enabled); if (tm_enabled == 0 && target_role != 0) { if (isp_enable_target_mode(isp, bus)) { ccb->ccb_h.status = CAM_REQ_CMP_ERR; destroy_lun_state(isp, tptr); tptr = NULL; goto done; } tm_enabled = 1; } /* * Now check to see whether this bus is in target mode already. * * If not, a later role change into target mode will finish the job. */ if (tm_enabled == 0) { ISP_SET_PC(isp, bus, tm_enable_defer, 1); ccb->ccb_h.status = CAM_REQ_CMP; - xpt_print(ccb->ccb_h.path, "Target Mode Not Enabled Yet- Lun Enables Deferred\n"); + xpt_print(ccb->ccb_h.path, "Target Mode not enabled yet- lun enable deferred\n"); goto done; } /* * Enable the lun. */ ccb->ccb_h.status = isp_enable_deferred(isp, bus, lun); done: - if (ccb->ccb_h.status != CAM_REQ_CMP && tptr) { - destroy_lun_state(isp, tptr); - tptr = NULL; + if (ccb->ccb_h.status != CAM_REQ_CMP) { + if (tptr) { + destroy_lun_state(isp, tptr); + tptr = NULL; + } + } else { + tptr->enabled = 1; } if (tptr) { rls_lun_statep(isp, tptr); } - isp->isp_osinfo.tmbusy = 0; - if (isp->isp_osinfo.tmwanted) { - isp->isp_osinfo.tmwanted = 0; - wakeup(isp); - } + + /* + * And we're outta here.... + */ + isp_tmunlk(isp); xpt_done(ccb); } -static void +static cam_status isp_enable_deferred_luns(ispsoftc_t *isp, int bus) { + tstate_t *tptr = NULL; + struct tslist *lhp; + int i, n; + + ISP_GET_PC(isp, bus, tm_enabled, i); + if (i == 1) { + return (CAM_REQ_CMP); + } + ISP_GET_PC(isp, bus, tm_enable_defer, i); + if (i == 0) { + return (CAM_REQ_CMP); + } /* - * XXX: not entirely implemented yet + * If this succeeds, it will set tm_enable */ - (void) isp_enable_deferred(isp, bus, 0); + if (isp_enable_target_mode(isp, bus)) { + return (CAM_REQ_CMP_ERR); + } + isp_tmlock(isp, "isp_enable_deferred_luns"); + for (n = i = 0; i < LUN_HASH_SIZE; i++) { + ISP_GET_PC_ADDR(isp, bus, lun_hash[i], lhp); + SLIST_FOREACH(tptr, lhp, next) { + tptr->hold++; + if (tptr->enabled == 0) { + if (isp_enable_deferred(isp, bus, xpt_path_lun_id(tptr->owner)) == 0) { + tptr->enabled = 1; + n++; + } + } else { + n++; + } + tptr->hold--; + } + } + isp_tmunlk(isp); + if (n == 0) { + return (CAM_REQ_CMP_ERR); + } + ISP_SET_PC(isp, bus, tm_enable_defer, 0); + return (CAM_REQ_CMP); } -static uint32_t +static cam_status isp_enable_deferred(ispsoftc_t *isp, int bus, lun_id_t lun) { cam_status status; + int luns_already_enabled = ISP_FC_PC(isp, bus)->tm_luns_enabled; isp_prt(isp, ISP_LOGTINFO, "%s: bus %d lun %u", __func__, bus, lun); - if (IS_24XX(isp) || (IS_FC(isp) && ISP_FC_PC(isp, bus)->tm_luns_enabled)) { + if (IS_24XX(isp) || (IS_FC(isp) && luns_already_enabled)) { status = CAM_REQ_CMP; } else { int cmd_cnt, not_cnt; if (IS_23XX(isp)) { cmd_cnt = DFLT_CMND_CNT; not_cnt = DFLT_INOT_CNT; } else { cmd_cnt = 64; not_cnt = 8; } status = CAM_REQ_INPROG; isp->isp_osinfo.rptr = &status; if (isp_lun_cmd(isp, RQSTYPE_ENABLE_LUN, bus, lun, DFLT_CMND_CNT, DFLT_INOT_CNT)) { status = CAM_RESRC_UNAVAIL; } else { mtx_sleep(&status, &isp->isp_lock, PRIBIO, "isp_enable_deferred", 0); } isp->isp_osinfo.rptr = NULL; } - if (status == CAM_REQ_CMP) { ISP_SET_PC(isp, bus, tm_luns_enabled, 1); - isp_prt(isp, ISP_LOGTINFO, "bus %d lun %u now enabled for target mode", bus, lun); + isp_prt(isp, ISP_LOGCONFIG|ISP_LOGTINFO, "bus %d lun %u now enabled for target mode", bus, lun); } return (status); } static void isp_disable_lun(ispsoftc_t *isp, union ccb *ccb) { tstate_t *tptr = NULL; int bus; cam_status status; target_id_t target; lun_id_t lun; bus = XS_CHANNEL(ccb); target = ccb->ccb_h.target_id; lun = ccb->ccb_h.target_lun; + ISP_PATH_PRT(isp, ISP_LOGTDEBUG0|ISP_LOGCONFIG, ccb->ccb_h.path, "disabling lun %u\n", lun); if (target != CAM_TARGET_WILDCARD && target != 0) { ccb->ccb_h.status = CAM_TID_INVALID; xpt_done(ccb); return; } + if (target == CAM_TARGET_WILDCARD && lun != CAM_LUN_WILDCARD) { ccb->ccb_h.status = CAM_LUN_INVALID; xpt_done(ccb); return; } if (target != CAM_TARGET_WILDCARD && lun == CAM_LUN_WILDCARD) { ccb->ccb_h.status = CAM_LUN_INVALID; xpt_done(ccb); return; } - if (isp->isp_dblev & ISP_LOGTDEBUG0) { - xpt_print(ccb->ccb_h.path, "enabling lun 0x%x on channel %d\n", lun, bus); - } /* * See if we're busy disabling a lun now. */ - while (isp->isp_osinfo.tmbusy) { - isp->isp_osinfo.tmwanted = 1; - mtx_sleep(isp, &isp->isp_lock, PRIBIO, "want_isp_disable_lun", 0); - } - isp->isp_osinfo.tmbusy = 1; + isp_tmlock(isp, "isp_disable_lun"); status = CAM_REQ_INPROG; /* * Find the state pointer. */ if ((tptr = get_lun_statep(isp, bus, lun)) == NULL) { status = CAM_PATH_INVALID; goto done; } /* * If we're a 24XX card, we're done. */ if (IS_24XX(isp)) { status = CAM_REQ_CMP; goto done; } /* * For SCC FW, we only deal with lun zero. */ if (IS_FC(isp)) { lun = 0; } - isp->isp_osinfo.rptr = &status; if (isp_lun_cmd(isp, RQSTYPE_ENABLE_LUN, bus, lun, 0, 0)) { status = CAM_RESRC_UNAVAIL; } else { mtx_sleep(ccb, &isp->isp_lock, PRIBIO, "isp_disable_lun", 0); } + isp->isp_osinfo.rptr = NULL; done: - ccb->ccb_h.status = status; if (status == CAM_REQ_CMP) { - xpt_print(ccb->ccb_h.path, "now disabled for target mode\n"); + tptr->enabled = 0; + /* + * If we have no more luns enabled for this bus, delete all tracked wwns for it (if we are FC) + * and disable target mode. + */ + if (is_any_lun_enabled(isp, bus) == 0) { + isp_del_all_wwn_entries(isp, bus); + if (isp_disable_target_mode(isp, bus)) { + status = CAM_REQ_CMP_ERR; + } + } } - if (tptr) { + ccb->ccb_h.status = status; + if (status == CAM_REQ_CMP) { + xpt_print(ccb->ccb_h.path, "lun now disabled for target mode\n"); destroy_lun_state(isp, tptr); + } else { + if (tptr) + rls_lun_statep(isp, tptr); } - isp->isp_osinfo.rptr = NULL; - isp->isp_osinfo.tmbusy = 0; - if (isp->isp_osinfo.tmwanted) { - isp->isp_osinfo.tmwanted = 0; - wakeup(isp); - } + isp_tmunlk(isp); xpt_done(ccb); } static int isp_enable_target_mode(ispsoftc_t *isp, int bus) { - int ct; + int tm_enabled; - ISP_GET_PC(isp, bus, tm_enabled, ct); - if (ct != 0) { + ISP_GET_PC(isp, bus, tm_enabled, tm_enabled); + if (tm_enabled != 0) { return (0); } - if (IS_SCSI(isp)) { mbreg_t mbs; - MBSINIT(&mbs, MBOX_ENABLE_TARGET_MODE, MBLOGALL, 0); mbs.param[0] = MBOX_ENABLE_TARGET_MODE; mbs.param[1] = ENABLE_TARGET_FLAG|ENABLE_TQING_FLAG; mbs.param[2] = bus << 7; if (isp_control(isp, ISPCTL_RUN_MBOXCMD, &mbs) < 0 || mbs.param[0] != MBOX_COMMAND_COMPLETE) { - isp_prt(isp, ISP_LOGERR, "Unable to add Target Role to Bus %d", bus); + isp_prt(isp, ISP_LOGERR, "Unable to enable Target Role on Bus %d", bus); return (EIO); } - SDPARAM(isp, bus)->role |= ISP_ROLE_TARGET; } ISP_SET_PC(isp, bus, tm_enabled, 1); - isp_prt(isp, ISP_LOGINFO, "Target Role added to Bus %d", bus); + isp_prt(isp, ISP_LOGINFO, "Target Role enabled on Bus %d", bus); return (0); } -#ifdef NEEDED static int isp_disable_target_mode(ispsoftc_t *isp, int bus) { - int ct; + int tm_enabled; - ISP_GET_PC(isp, bus, tm_enabled, ct); - if (ct == 0) { + ISP_GET_PC(isp, bus, tm_enabled, tm_enabled); + if (tm_enabled == 0) { return (0); } - if (IS_SCSI(isp)) { mbreg_t mbs; - MBSINIT(&mbs, MBOX_ENABLE_TARGET_MODE, MBLOGALL, 0); mbs.param[2] = bus << 7; if (isp_control(isp, ISPCTL_RUN_MBOXCMD, &mbs) < 0 || mbs.param[0] != MBOX_COMMAND_COMPLETE) { - isp_prt(isp, ISP_LOGERR, "Unable to subtract Target Role to Bus %d", bus); + isp_prt(isp, ISP_LOGERR, "Unable to disable Target Role on Bus %d", bus); return (EIO); } - SDPARAM(isp, bus)->role &= ~ISP_ROLE_TARGET; } ISP_SET_PC(isp, bus, tm_enabled, 0); - isp_prt(isp, ISP_LOGINFO, "Target Role subtracted from Bus %d", bus); + isp_prt(isp, ISP_LOGINFO, "Target Role disabled onon Bus %d", bus); return (0); } -#endif static void isp_ledone(ispsoftc_t *isp, lun_entry_t *lep) { uint32_t *rptr; rptr = isp->isp_osinfo.rptr; if (lep->le_status != LUN_OK) { isp_prt(isp, ISP_LOGERR, "ENABLE/MODIFY LUN returned 0x%x", lep->le_status); if (rptr) { *rptr = CAM_REQ_CMP_ERR; wakeup_one(rptr); } } else { if (rptr) { *rptr = CAM_REQ_CMP; wakeup_one(rptr); } } } static void isp_target_start_ctio(ispsoftc_t *isp, union ccb *ccb) { void *qe; tstate_t *tptr; atio_private_data_t *atp; struct ccb_scsiio *cso = &ccb->csio; uint32_t dmaresult, handle; uint8_t local[QENTRY_LEN]; /* * Do some sanity checks. */ if (cso->dxfer_len == 0) { if ((ccb->ccb_h.flags & CAM_SEND_STATUS) == 0) { xpt_print(ccb->ccb_h.path, "a data transfer length of zero but no status to send is wrong\n"); ccb->ccb_h.status = CAM_REQ_INVALID; xpt_done(ccb); return; } } tptr = get_lun_statep(isp, XS_CHANNEL(ccb), XS_LUN(ccb)); if (tptr == NULL) { tptr = get_lun_statep(isp, XS_CHANNEL(ccb), CAM_LUN_WILDCARD); if (tptr == NULL) { xpt_print(ccb->ccb_h.path, "%s: [0x%x] cannot find tstate pointer in %s\n", __func__, cso->tag_id); dump_tstates(isp, XS_CHANNEL(ccb)); ccb->ccb_h.status = CAM_DEV_NOT_THERE; xpt_done(ccb); return; } } atp = isp_get_atpd(isp, tptr, cso->tag_id); if (atp == NULL) { xpt_print(ccb->ccb_h.path, "%s: [0x%x] cannot find private data adjunct\n", __func__, cso->tag_id); isp_dump_atpd(isp, tptr); ccb->ccb_h.status = CAM_REQ_CMP_ERR; xpt_done(ccb); return; } if (atp->dead) { xpt_print(ccb->ccb_h.path, "%s: [0x%x] stopping sending a CTIO for a dead command\n", __func__, cso->tag_id); ccb->ccb_h.status = CAM_REQ_ABORTED; xpt_done(ccb); return; } /* * Check to make sure we're still in target mode. */ if ((FCPARAM(isp, XS_CHANNEL(ccb))->role & ISP_ROLE_TARGET) == 0) { xpt_print(ccb->ccb_h.path, "%s: [0x%x] stopping sending a CTIO because we're no longer in target mode\n", __func__, cso->tag_id); ccb->ccb_h.status = CAM_PROVIDE_FAIL; xpt_done(ccb); return; } /* * Get some resources */ if (isp_get_pcmd(isp, ccb)) { rls_lun_statep(isp, tptr); xpt_print(ccb->ccb_h.path, "out of PCMDs\n"); cam_freeze_devq(ccb->ccb_h.path); cam_release_devq(ccb->ccb_h.path, RELSIM_RELEASE_AFTER_TIMEOUT, 0, 250, 0); ccb->ccb_h.status = CAM_REQUEUE_REQ; xpt_done(ccb); return; } qe = isp_getrqentry(isp); if (qe == NULL) { xpt_print(ccb->ccb_h.path, rqo, __func__); cam_freeze_devq(ccb->ccb_h.path); cam_release_devq(ccb->ccb_h.path, RELSIM_RELEASE_AFTER_TIMEOUT, 0, 250, 0); ccb->ccb_h.status = CAM_REQUEUE_REQ; goto out; } memset(local, 0, QENTRY_LEN); /* * We're either moving data or completing a command here. */ if (IS_24XX(isp)) { ct7_entry_t *cto = (ct7_entry_t *) local; cto->ct_header.rqs_entry_type = RQSTYPE_CTIO7; cto->ct_header.rqs_entry_count = 1; cto->ct_header.rqs_seqno = 1; cto->ct_nphdl = atp->nphdl; cto->ct_rxid = atp->tag; cto->ct_iid_lo = atp->portid; cto->ct_iid_hi = atp->portid >> 16; cto->ct_oxid = atp->oxid; cto->ct_vpidx = ISP_GET_VPIDX(isp, XS_CHANNEL(ccb)); cto->ct_scsi_status = cso->scsi_status; cto->ct_timeout = 120; cto->ct_flags = atp->tattr << CT7_TASK_ATTR_SHIFT; if (ccb->ccb_h.flags & CAM_SEND_STATUS) { cto->ct_flags |= CT7_SENDSTATUS; } if (cso->dxfer_len == 0) { cto->ct_flags |= CT7_FLAG_MODE1 | CT7_NO_DATA; if ((ccb->ccb_h.flags & CAM_SEND_SENSE) != 0) { int m = min(cso->sense_len, sizeof (struct scsi_sense_data)); cto->rsp.m1.ct_resplen = cto->ct_senselen = min(m, MAXRESPLEN_24XX); memcpy(cto->rsp.m1.ct_resp, &cso->sense_data, cto->ct_senselen); cto->ct_scsi_status |= (FCP_SNSLEN_VALID << 8); } } else { cto->ct_flags |= CT7_FLAG_MODE0; if ((cso->ccb_h.flags & CAM_DIR_MASK) == CAM_DIR_IN) { cto->ct_flags |= CT7_DATA_IN; } else { cto->ct_flags |= CT7_DATA_OUT; } cto->rsp.m0.reloff = atp->bytes_xfered; /* * Don't overrun the limits placed on us */ if (atp->bytes_xfered + cso->dxfer_len > atp->orig_datalen) { cso->dxfer_len = atp->orig_datalen - atp->bytes_xfered; } atp->last_xframt = cso->dxfer_len; cto->rsp.m0.ct_xfrlen = cso->dxfer_len; } if (cto->ct_flags & CT7_SENDSTATUS) { int lvl = (cso->scsi_status)? ISP_LOGTINFO : ISP_LOGTDEBUG0; cto->ct_resid = atp->orig_datalen - (atp->bytes_xfered + cso->dxfer_len); if (cto->ct_resid < 0) { cto->ct_scsi_status |= (FCP_RESID_OVERFLOW << 8); } else if (cto->ct_resid > 0) { cto->ct_scsi_status |= (FCP_RESID_UNDERFLOW << 8); } atp->state = ATPD_STATE_LAST_CTIO; ISP_PATH_PRT(isp, lvl, cso->ccb_h.path, "%s: CTIO7[%x] CDB0=%x scsi status %x flags %x resid %d xfrlen %u offset %u\n", __func__, cto->ct_rxid, atp->cdb0, cto->ct_scsi_status, cto->ct_flags, cto->ct_resid, cso->dxfer_len, atp->bytes_xfered); } else { cto->ct_resid = 0; ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, cso->ccb_h.path, "%s: CTIO7[%x] flags %x xfrlen %u offset %u\n", __func__, cto->ct_rxid, cto->ct_flags, cso->dxfer_len, atp->bytes_xfered); atp->state = ATPD_STATE_CTIO; } } else if (IS_FC(isp)) { ct2_entry_t *cto = (ct2_entry_t *) local; cto->ct_header.rqs_entry_type = RQSTYPE_CTIO2; cto->ct_header.rqs_entry_count = 1; cto->ct_header.rqs_seqno = 1; if (ISP_CAP_2KLOGIN(isp) == 0) { ((ct2e_entry_t *)cto)->ct_iid = cso->init_id; } else { cto->ct_iid = cso->init_id; if (ISP_CAP_SCCFW(isp) == 0) { cto->ct_lun = ccb->ccb_h.target_lun; } } cto->ct_rxid = cso->tag_id; if (cso->dxfer_len == 0) { cto->ct_flags |= CT2_FLAG_MODE1 | CT2_NO_DATA | CT2_SENDSTATUS; cto->rsp.m1.ct_scsi_status = cso->scsi_status; cto->ct_resid = atp->orig_datalen - atp->bytes_xfered; if (cto->ct_resid < 0) { cto->rsp.m1.ct_scsi_status |= CT2_DATA_OVER; } else if (cto->ct_resid > 0) { cto->rsp.m1.ct_scsi_status |= CT2_DATA_UNDER; } if ((ccb->ccb_h.flags & CAM_SEND_SENSE) != 0) { int m = min(cso->sense_len, MAXRESPLEN); memcpy(cto->rsp.m1.ct_resp, &cso->sense_data, m); cto->rsp.m1.ct_senselen = m; cto->rsp.m1.ct_scsi_status |= CT2_SNSLEN_VALID; } else if (cso->scsi_status == SCSI_STATUS_CHECK_COND) { /* * XXX: DEBUG */ xpt_print(ccb->ccb_h.path, "CHECK CONDITION being sent without associated SENSE DATA for CDB=0x%x\n", atp->cdb0); } } else { cto->ct_flags |= CT2_FLAG_MODE0; if ((cso->ccb_h.flags & CAM_DIR_MASK) == CAM_DIR_IN) { cto->ct_flags |= CT2_DATA_IN; } else { cto->ct_flags |= CT2_DATA_OUT; } cto->ct_reloff = atp->bytes_xfered; cto->rsp.m0.ct_xfrlen = cso->dxfer_len; /* * Don't overrun the limits placed on us */ if (atp->bytes_xfered + cso->dxfer_len > atp->orig_datalen) { cso->dxfer_len = atp->orig_datalen - atp->bytes_xfered; } if ((ccb->ccb_h.flags & CAM_SEND_STATUS) != 0) { cto->ct_flags |= CT2_SENDSTATUS; cto->rsp.m0.ct_scsi_status = cso->scsi_status; cto->ct_resid = atp->orig_datalen - (atp->bytes_xfered + cso->dxfer_len); if (cto->ct_resid < 0) { cto->rsp.m0.ct_scsi_status |= CT2_DATA_OVER; } else if (cto->ct_resid > 0) { cto->rsp.m0.ct_scsi_status |= CT2_DATA_UNDER; } } else { atp->last_xframt = cso->dxfer_len; } /* * If we're sending data and status back together, * we can't also send back sense data as well. */ ccb->ccb_h.flags &= ~CAM_SEND_SENSE; } if (cto->ct_flags & CT2_SENDSTATUS) { int lvl = (cso->scsi_status)? ISP_LOGTINFO : ISP_LOGTDEBUG0; cto->ct_flags |= CT2_CCINCR; atp->state = ATPD_STATE_LAST_CTIO; ISP_PATH_PRT(isp, lvl, cso->ccb_h.path, "%s: CTIO2[%x] CDB0=%x scsi status %x flags %x resid %d xfrlen %u offset %u\n", __func__, cto->ct_rxid, atp->cdb0, cto->rsp.m0.ct_scsi_status, cto->ct_flags, cto->ct_resid, cso->dxfer_len, atp->bytes_xfered); } else { cto->ct_resid = 0; atp->state = ATPD_STATE_CTIO; ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, ccb->ccb_h.path, "%s: CTIO2[%x] flags %x xfrlen %u offset %u\n", __func__, cto->ct_rxid, cto->ct_flags, cso->dxfer_len, atp->bytes_xfered); } cto->ct_timeout = 10; } else { ct_entry_t *cto = (ct_entry_t *) local; cto->ct_header.rqs_entry_type = RQSTYPE_CTIO; cto->ct_header.rqs_entry_count = 1; cto->ct_header.rqs_seqno = 1; cto->ct_iid = cso->init_id; cto->ct_iid |= XS_CHANNEL(ccb) << 7; cto->ct_tgt = ccb->ccb_h.target_id; cto->ct_lun = ccb->ccb_h.target_lun; cto->ct_fwhandle = cso->tag_id >> 16; if (AT_HAS_TAG(cso->tag_id)) { cto->ct_tag_val = cso->tag_id; cto->ct_flags |= CT_TQAE; } if (ccb->ccb_h.flags & CAM_DIS_DISCONNECT) { cto->ct_flags |= CT_NODISC; } if (cso->dxfer_len == 0) { cto->ct_flags |= CT_NO_DATA; } else if ((cso->ccb_h.flags & CAM_DIR_MASK) == CAM_DIR_IN) { cto->ct_flags |= CT_DATA_IN; } else { cto->ct_flags |= CT_DATA_OUT; } if (ccb->ccb_h.flags & CAM_SEND_STATUS) { cto->ct_flags |= CT_SENDSTATUS|CT_CCINCR; cto->ct_scsi_status = cso->scsi_status; cto->ct_resid = cso->resid; ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, ccb->ccb_h.path, "%s: CTIO[%x] scsi status %x resid %d tag_id %x\n", __func__, cto->ct_fwhandle, cso->scsi_status, cso->resid, cso->tag_id); } ccb->ccb_h.flags &= ~CAM_SEND_SENSE; cto->ct_timeout = 10; } if (isp_allocate_xs_tgt(isp, ccb, &handle)) { xpt_print(ccb->ccb_h.path, "No XFLIST pointers for %s\n", __func__); ccb->ccb_h.status = CAM_REQUEUE_REQ; goto out; } /* * Call the dma setup routines for this entry (and any subsequent * CTIOs) if there's data to move, and then tell the f/w it's got * new things to play with. As with isp_start's usage of DMA setup, * any swizzling is done in the machine dependent layer. Because * of this, we put the request onto the queue area first in native * format. */ if (IS_24XX(isp)) { ct7_entry_t *cto = (ct7_entry_t *) local; cto->ct_syshandle = handle; } else if (IS_FC(isp)) { ct2_entry_t *cto = (ct2_entry_t *) local; cto->ct_syshandle = handle; } else { ct_entry_t *cto = (ct_entry_t *) local; cto->ct_syshandle = handle; } dmaresult = ISP_DMASETUP(isp, cso, (ispreq_t *) local); if (dmaresult == CMD_QUEUED) { isp->isp_nactive++; ccb->ccb_h.status |= CAM_SIM_QUEUED; rls_lun_statep(isp, tptr); return; } if (dmaresult == CMD_EAGAIN) { ccb->ccb_h.status = CAM_REQUEUE_REQ; } else { ccb->ccb_h.status = CAM_REQ_CMP_ERR; } isp_destroy_tgt_handle(isp, handle); out: rls_lun_statep(isp, tptr); isp_free_pcmd(isp, ccb); xpt_done(ccb); } static void isp_refire_putback_atio(void *arg) { union ccb *ccb = arg; ispsoftc_t *isp = XS_ISP(ccb); ISP_LOCK(isp); isp_target_putback_atio(ccb); ISP_UNLOCK(isp); } static void isp_target_putback_atio(union ccb *ccb) { ispsoftc_t *isp; struct ccb_scsiio *cso; void *qe; isp = XS_ISP(ccb); qe = isp_getrqentry(isp); if (qe == NULL) { xpt_print(ccb->ccb_h.path, rqo, __func__); (void) timeout(isp_refire_putback_atio, ccb, 10); return; } memset(qe, 0, QENTRY_LEN); cso = &ccb->csio; if (IS_FC(isp)) { at2_entry_t local, *at = &local; ISP_MEMZERO(at, sizeof (at2_entry_t)); at->at_header.rqs_entry_type = RQSTYPE_ATIO2; at->at_header.rqs_entry_count = 1; if (ISP_CAP_SCCFW(isp)) { at->at_scclun = (uint16_t) ccb->ccb_h.target_lun; } else { at->at_lun = (uint8_t) ccb->ccb_h.target_lun; } at->at_status = CT_OK; at->at_rxid = cso->tag_id; at->at_iid = cso->ccb_h.target_id; isp_put_atio2(isp, at, qe); } else { at_entry_t local, *at = &local; ISP_MEMZERO(at, sizeof (at_entry_t)); at->at_header.rqs_entry_type = RQSTYPE_ATIO; at->at_header.rqs_entry_count = 1; at->at_iid = cso->init_id; at->at_iid |= XS_CHANNEL(ccb) << 7; at->at_tgt = cso->ccb_h.target_id; at->at_lun = cso->ccb_h.target_lun; at->at_status = CT_OK; at->at_tag_val = AT_GET_TAG(cso->tag_id); at->at_handle = AT_GET_HANDLE(cso->tag_id); isp_put_atio(isp, at, qe); } ISP_TDQE(isp, "isp_target_putback_atio", isp->isp_reqidx, qe); ISP_SYNC_REQUEST(isp); isp_complete_ctio(ccb); } static void isp_complete_ctio(union ccb *ccb) { if ((ccb->ccb_h.status & CAM_STATUS_MASK) == CAM_REQ_INPROG) { ccb->ccb_h.status |= CAM_REQ_CMP; } ccb->ccb_h.status &= ~CAM_SIM_QUEUED; isp_free_pcmd(XS_ISP(ccb), ccb); xpt_done(ccb); } /* * Handle ATIO stuff that the generic code can't. * This means handling CDBs. */ static void isp_handle_platform_atio(ispsoftc_t *isp, at_entry_t *aep) { tstate_t *tptr; int status, bus; struct ccb_accept_tio *atiop; atio_private_data_t *atp; /* * The firmware status (except for the QLTM_SVALID bit) * indicates why this ATIO was sent to us. * * If QLTM_SVALID is set, the firmware has recommended Sense Data. * * If the DISCONNECTS DISABLED bit is set in the flags field, * we're still connected on the SCSI bus. */ status = aep->at_status; if ((status & ~QLTM_SVALID) == AT_PHASE_ERROR) { /* * Bus Phase Sequence error. We should have sense data * suggested by the f/w. I'm not sure quite yet what * to do about this for CAM. */ isp_prt(isp, ISP_LOGWARN, "PHASE ERROR"); isp_endcmd(isp, aep, SCSI_STATUS_BUSY, 0); return; } if ((status & ~QLTM_SVALID) != AT_CDB) { isp_prt(isp, ISP_LOGWARN, "bad atio (0x%x) leaked to platform", status); isp_endcmd(isp, aep, SCSI_STATUS_BUSY, 0); return; } bus = GET_BUS_VAL(aep->at_iid); tptr = get_lun_statep(isp, bus, aep->at_lun); if (tptr == NULL) { tptr = get_lun_statep(isp, bus, CAM_LUN_WILDCARD); if (tptr == NULL) { /* * Because we can't autofeed sense data back with * a command for parallel SCSI, we can't give back * a CHECK CONDITION. We'll give back a BUSY status * instead. This works out okay because the only * time we should, in fact, get this, is in the * case that somebody configured us without the * blackhole driver, so they get what they deserve. */ isp_endcmd(isp, aep, SCSI_STATUS_BUSY, 0); return; } } atp = isp_get_atpd(isp, tptr, 0); atiop = (struct ccb_accept_tio *) SLIST_FIRST(&tptr->atios); if (atiop == NULL || atp == NULL) { /* * Because we can't autofeed sense data back with * a command for parallel SCSI, we can't give back * a CHECK CONDITION. We'll give back a QUEUE FULL status * instead. This works out okay because the only time we * should, in fact, get this, is in the case that we've * run out of ATIOS. */ xpt_print(tptr->owner, "no %s for lun %d from initiator %d\n", (atp == NULL && atiop == NULL)? "ATIOs *or* ATPS" : ((atp == NULL)? "ATPs" : "ATIOs"), aep->at_lun, aep->at_iid); isp_endcmd(isp, aep, SCSI_STATUS_BUSY, 0); if (atp) { isp_put_atpd(isp, tptr, atp); } rls_lun_statep(isp, tptr); return; } atp->tag = aep->at_tag_val; if (atp->tag == 0) { atp->tag = ~0; } atp->state = ATPD_STATE_ATIO; SLIST_REMOVE_HEAD(&tptr->atios, sim_links.sle); tptr->atio_count--; ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, atiop->ccb_h.path, "Take FREE ATIO count now %d\n", tptr->atio_count); atiop->ccb_h.target_id = aep->at_tgt; atiop->ccb_h.target_lun = aep->at_lun; if (aep->at_flags & AT_NODISC) { atiop->ccb_h.flags = CAM_DIS_DISCONNECT; } else { atiop->ccb_h.flags = 0; } if (status & QLTM_SVALID) { size_t amt = ISP_MIN(QLTM_SENSELEN, sizeof (atiop->sense_data)); atiop->sense_len = amt; ISP_MEMCPY(&atiop->sense_data, aep->at_sense, amt); } else { atiop->sense_len = 0; } atiop->init_id = GET_IID_VAL(aep->at_iid); atiop->cdb_len = aep->at_cdblen; ISP_MEMCPY(atiop->cdb_io.cdb_bytes, aep->at_cdb, aep->at_cdblen); atiop->ccb_h.status = CAM_CDB_RECVD; /* * Construct a tag 'id' based upon tag value (which may be 0..255) * and the handle (which we have to preserve). */ atiop->tag_id = atp->tag; if (aep->at_flags & AT_TQAE) { atiop->tag_action = aep->at_tag_type; atiop->ccb_h.status |= CAM_TAG_ACTION_VALID; } atp->orig_datalen = 0; atp->bytes_xfered = 0; atp->last_xframt = 0; atp->lun = aep->at_lun; atp->nphdl = aep->at_iid; atp->portid = PORT_NONE; atp->oxid = 0; atp->cdb0 = atiop->cdb_io.cdb_bytes[0]; atp->tattr = aep->at_tag_type; atp->state = ATPD_STATE_CAM; ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, tptr->owner, "ATIO[%x] CDB=0x%x lun %d\n", aep->at_tag_val, atp->cdb0, atp->lun); rls_lun_statep(isp, tptr); } static void isp_handle_platform_atio2(ispsoftc_t *isp, at2_entry_t *aep) { lun_id_t lun; fcportdb_t *lp; tstate_t *tptr; struct ccb_accept_tio *atiop; uint16_t nphdl; atio_private_data_t *atp; inot_private_data_t *ntp; /* * The firmware status (except for the QLTM_SVALID bit) * indicates why this ATIO was sent to us. * * If QLTM_SVALID is set, the firmware has recommended Sense Data. */ if ((aep->at_status & ~QLTM_SVALID) != AT_CDB) { isp_prt(isp, ISP_LOGWARN, "bogus atio (0x%x) leaked to platform", aep->at_status); isp_endcmd(isp, aep, SCSI_STATUS_BUSY, 0); return; } if (ISP_CAP_SCCFW(isp)) { lun = aep->at_scclun; } else { lun = aep->at_lun; } if (ISP_CAP_2KLOGIN(isp)) { nphdl = ((at2e_entry_t *)aep)->at_iid; } else { nphdl = aep->at_iid; } tptr = get_lun_statep(isp, 0, lun); if (tptr == NULL) { tptr = get_lun_statep(isp, 0, CAM_LUN_WILDCARD); if (tptr == NULL) { isp_prt(isp, ISP_LOGTDEBUG0, "[0x%x] no state pointer for lun %d", aep->at_rxid, lun); isp_endcmd(isp, aep, SCSI_STATUS_CHECK_COND | ECMD_SVALID | (0x5 << 12) | (0x25 << 16), 0); return; } } /* * Start any commands pending resources first. */ if (tptr->restart_queue) { inot_private_data_t *restart_queue = tptr->restart_queue; tptr->restart_queue = NULL; while (restart_queue) { ntp = restart_queue; restart_queue = ntp->rd.nt.nt_hba; isp_prt(isp, ISP_LOGTDEBUG0, "%s: restarting resrc deprived %x", __func__, ((at2_entry_t *)ntp->rd.data)->at_rxid); isp_handle_platform_atio2(isp, (at2_entry_t *) ntp->rd.data); isp_put_ntpd(isp, tptr, ntp); /* * If a recursion caused the restart queue to start to fill again, * stop and splice the new list on top of the old list and restore * it and go to noresrc. */ if (tptr->restart_queue) { ntp = tptr->restart_queue; tptr->restart_queue = restart_queue; while (restart_queue->rd.nt.nt_hba) { restart_queue = restart_queue->rd.nt.nt_hba; } restart_queue->rd.nt.nt_hba = ntp; goto noresrc; } } } atiop = (struct ccb_accept_tio *) SLIST_FIRST(&tptr->atios); if (atiop == NULL) { goto noresrc; } atp = isp_get_atpd(isp, tptr, 0); if (atp == NULL) { goto noresrc; } atp->tag = aep->at_rxid; atp->state = ATPD_STATE_ATIO; SLIST_REMOVE_HEAD(&tptr->atios, sim_links.sle); tptr->atio_count--; ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, atiop->ccb_h.path, "Take FREE ATIO count now %d\n", tptr->atio_count); atiop->ccb_h.target_id = FCPARAM(isp, 0)->isp_loopid; atiop->ccb_h.target_lun = lun; /* * We don't get 'suggested' sense data as we do with SCSI cards. */ atiop->sense_len = 0; if (ISP_CAP_2KLOGIN(isp)) { /* * NB: We could not possibly have 2K logins if we * NB: also did not have SCC FW. */ atiop->init_id = ((at2e_entry_t *)aep)->at_iid; } else { atiop->init_id = aep->at_iid; } /* * If we're not in the port database, add ourselves. */ if (!IS_2100(isp) && isp_find_pdb_by_loopid(isp, 0, atiop->init_id, &lp) == 0) { uint64_t iid = (((uint64_t) aep->at_wwpn[0]) << 48) | (((uint64_t) aep->at_wwpn[1]) << 32) | (((uint64_t) aep->at_wwpn[2]) << 16) | (((uint64_t) aep->at_wwpn[3]) << 0); /* * However, make sure we delete ourselves if otherwise * we were there but at a different loop id. */ if (isp_find_pdb_by_wwn(isp, 0, iid, &lp)) { isp_del_wwn_entry(isp, 0, iid, lp->handle, lp->portid); } isp_add_wwn_entry(isp, 0, iid, atiop->init_id, PORT_ANY); } atiop->cdb_len = ATIO2_CDBLEN; ISP_MEMCPY(atiop->cdb_io.cdb_bytes, aep->at_cdb, ATIO2_CDBLEN); atiop->ccb_h.status = CAM_CDB_RECVD; atiop->tag_id = atp->tag; switch (aep->at_taskflags & ATIO2_TC_ATTR_MASK) { case ATIO2_TC_ATTR_SIMPLEQ: atiop->ccb_h.flags = CAM_TAG_ACTION_VALID; atiop->tag_action = MSG_SIMPLE_Q_TAG; break; case ATIO2_TC_ATTR_HEADOFQ: atiop->ccb_h.flags = CAM_TAG_ACTION_VALID; atiop->tag_action = MSG_HEAD_OF_Q_TAG; break; case ATIO2_TC_ATTR_ORDERED: atiop->ccb_h.flags = CAM_TAG_ACTION_VALID; atiop->tag_action = MSG_ORDERED_Q_TAG; break; case ATIO2_TC_ATTR_ACAQ: /* ?? */ case ATIO2_TC_ATTR_UNTAGGED: default: atiop->tag_action = 0; break; } atp->orig_datalen = aep->at_datalen; atp->bytes_xfered = 0; atp->last_xframt = 0; atp->lun = lun; atp->nphdl = atiop->init_id; atp->sid = PORT_ANY; atp->oxid = aep->at_oxid; atp->cdb0 = aep->at_cdb[0]; atp->tattr = aep->at_taskflags & ATIO2_TC_ATTR_MASK; atp->state = ATPD_STATE_CAM; xpt_done((union ccb *)atiop); ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, tptr->owner, "ATIO2[%x] CDB=0x%x lun %d datalen %u\n", aep->at_rxid, atp->cdb0, lun, atp->orig_datalen); rls_lun_statep(isp, tptr); return; noresrc: ntp = isp_get_ntpd(isp, tptr); if (ntp == NULL) { rls_lun_statep(isp, tptr); isp_endcmd(isp, aep, nphdl, 0, SCSI_STATUS_BUSY, 0); return; } memcpy(ntp->rd.data, aep, QENTRY_LEN); ntp->rd.nt.nt_hba = tptr->restart_queue; tptr->restart_queue = ntp; rls_lun_statep(isp, tptr); } static void isp_handle_platform_atio7(ispsoftc_t *isp, at7_entry_t *aep) { int cdbxlen; uint16_t lun, chan, nphdl = NIL_HANDLE; uint32_t did, sid; uint64_t wwn = INI_NONE; fcportdb_t *lp; tstate_t *tptr; struct ccb_accept_tio *atiop; atio_private_data_t *atp = NULL; inot_private_data_t *ntp; did = (aep->at_hdr.d_id[0] << 16) | (aep->at_hdr.d_id[1] << 8) | aep->at_hdr.d_id[2]; sid = (aep->at_hdr.s_id[0] << 16) | (aep->at_hdr.s_id[1] << 8) | aep->at_hdr.s_id[2]; lun = (aep->at_cmnd.fcp_cmnd_lun[0] << 8) | aep->at_cmnd.fcp_cmnd_lun[1]; /* * Find the N-port handle, and Virtual Port Index for this command. * * If we can't, we're somewhat in trouble because we can't actually respond w/o that information. * We also, as a matter of course, need to know the WWN of the initiator too. */ if (ISP_CAP_MULTI_ID(isp)) { /* * Find the right channel based upon D_ID */ isp_find_chan_by_did(isp, did, &chan); if (chan == ISP_NOCHAN) { NANOTIME_T now; /* * If we don't recognizer our own D_DID, terminate the exchange, unless we're within 2 seconds of startup * It's a bit tricky here as we need to stash this command *somewhere*. */ GET_NANOTIME(&now); if (NANOTIME_SUB(&isp->isp_init_time, &now) > 2000000000ULL) { isp_prt(isp, ISP_LOGWARN, "%s: [RX_ID 0x%x] D_ID %x not found on any channel- dropping", __func__, aep->at_rxid, did); isp_endcmd(isp, aep, NIL_HANDLE, ISP_NOCHAN, ECMD_TERMINATE, 0); return; } tptr = get_lun_statep(isp, 0, 0); if (tptr == NULL) { tptr = get_lun_statep(isp, 0, CAM_LUN_WILDCARD); if (tptr == NULL) { isp_prt(isp, ISP_LOGWARN, "%s: [RX_ID 0x%x] D_ID %x not found on any channel and no tptr- dropping", __func__, aep->at_rxid, did); isp_endcmd(isp, aep, NIL_HANDLE, ISP_NOCHAN, ECMD_TERMINATE, 0); return; } } isp_prt(isp, ISP_LOGWARN, "%s: [RX_ID 0x%x] D_ID %x not found on any channel- deferring", __func__, aep->at_rxid, did); goto noresrc; } isp_prt(isp, ISP_LOGTDEBUG0, "%s: [RX_ID 0x%x] D_ID 0x%06x found on Chan %d for S_ID 0x%06x", __func__, aep->at_rxid, did, chan, sid); } else { chan = 0; } /* * Find the PDB entry for this initiator */ if (isp_find_pdb_by_sid(isp, chan, sid, &lp) == 0) { /* * If we're not in the port database terminate the exchange. */ isp_prt(isp, ISP_LOGTINFO, "%s: [RX_ID 0x%x] D_ID 0x%06x found on Chan %d for S_ID 0x%06x wasn't in PDB already", __func__, aep->at_rxid, did, chan, sid); isp_endcmd(isp, aep, NIL_HANDLE, chan, ECMD_TERMINATE, 0); return; } nphdl = lp->handle; wwn = lp->port_wwn; /* * Get the tstate pointer */ tptr = get_lun_statep(isp, chan, lun); if (tptr == NULL) { tptr = get_lun_statep(isp, chan, CAM_LUN_WILDCARD); if (tptr == NULL) { isp_prt(isp, ISP_LOGTDEBUG0, "[0x%x] no state pointer for lun %d or wildcard", aep->at_rxid, lun); isp_endcmd(isp, aep, nphdl, chan, SCSI_STATUS_CHECK_COND | ECMD_SVALID | (0x5 << 12) | (0x25 << 16), 0); return; } } /* * Start any commands pending resources first. */ if (tptr->restart_queue) { inot_private_data_t *restart_queue = tptr->restart_queue; tptr->restart_queue = NULL; while (restart_queue) { ntp = restart_queue; restart_queue = ntp->rd.nt.nt_hba; isp_prt(isp, ISP_LOGTDEBUG0, "%s: restarting resrc deprived %x", __func__, ((at7_entry_t *)ntp->rd.data)->at_rxid); isp_handle_platform_atio7(isp, (at7_entry_t *) ntp->rd.data); isp_put_ntpd(isp, tptr, ntp); /* * If a recursion caused the restart queue to start to fill again, * stop and splice the new list on top of the old list and restore * it and go to noresrc. */ if (tptr->restart_queue) { if (restart_queue) { ntp = tptr->restart_queue; tptr->restart_queue = restart_queue; while (restart_queue->rd.nt.nt_hba) { restart_queue = restart_queue->rd.nt.nt_hba; } restart_queue->rd.nt.nt_hba = ntp; } goto noresrc; } } } /* * If the f/w is out of resources, just send a BUSY status back. */ if (aep->at_rxid == AT7_NORESRC_RXID) { rls_lun_statep(isp, tptr); isp_endcmd(isp, aep, nphdl, chan, SCSI_BUSY, 0); return; } /* * If we're out of resources, just send a BUSY status back. */ atiop = (struct ccb_accept_tio *) SLIST_FIRST(&tptr->atios); if (atiop == NULL) { isp_prt(isp, ISP_LOGTDEBUG0, "[0x%x] out of atios", aep->at_rxid); goto noresrc; } atp = isp_get_atpd(isp, tptr, 0); if (atp == NULL) { isp_prt(isp, ISP_LOGTDEBUG0, "[0x%x] out of atps", aep->at_rxid); goto noresrc; } if (isp_get_atpd(isp, tptr, aep->at_rxid)) { isp_prt(isp, ISP_LOGTDEBUG0, "[0x%x] tag wraparound in isp_handle_platforms_atio7 (N-Port Handle 0x%04x S_ID 0x%04x OX_ID 0x%04x)\n", aep->at_rxid, nphdl, sid, aep->at_hdr.ox_id); /* * It's not a "no resource" condition- but we can treat it like one */ goto noresrc; } atp->tag = aep->at_rxid; atp->state = ATPD_STATE_ATIO; SLIST_REMOVE_HEAD(&tptr->atios, sim_links.sle); tptr->atio_count--; ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, atiop->ccb_h.path, "Take FREE ATIO count now %d\n", tptr->atio_count); atiop->init_id = nphdl; atiop->ccb_h.target_id = FCPARAM(isp, chan)->isp_loopid; atiop->ccb_h.target_lun = lun; atiop->sense_len = 0; cdbxlen = aep->at_cmnd.fcp_cmnd_alen_datadir >> FCP_CMND_ADDTL_CDBLEN_SHIFT; if (cdbxlen) { isp_prt(isp, ISP_LOGWARN, "additional CDBLEN ignored"); } cdbxlen = sizeof (aep->at_cmnd.cdb_dl.sf.fcp_cmnd_cdb); ISP_MEMCPY(atiop->cdb_io.cdb_bytes, aep->at_cmnd.cdb_dl.sf.fcp_cmnd_cdb, cdbxlen); atiop->cdb_len = cdbxlen; atiop->ccb_h.status = CAM_CDB_RECVD; atiop->tag_id = atp->tag; switch (aep->at_cmnd.fcp_cmnd_task_attribute & FCP_CMND_TASK_ATTR_MASK) { case FCP_CMND_TASK_ATTR_SIMPLE: atiop->ccb_h.flags = CAM_TAG_ACTION_VALID; atiop->tag_action = MSG_SIMPLE_Q_TAG; break; case FCP_CMND_TASK_ATTR_HEAD: atiop->ccb_h.flags = CAM_TAG_ACTION_VALID; atiop->tag_action = MSG_HEAD_OF_Q_TAG; break; case FCP_CMND_TASK_ATTR_ORDERED: atiop->ccb_h.flags = CAM_TAG_ACTION_VALID; atiop->tag_action = MSG_ORDERED_Q_TAG; break; default: /* FALLTHROUGH */ case FCP_CMND_TASK_ATTR_ACA: case FCP_CMND_TASK_ATTR_UNTAGGED: atiop->tag_action = 0; break; } atp->orig_datalen = aep->at_cmnd.cdb_dl.sf.fcp_cmnd_dl; atp->bytes_xfered = 0; atp->last_xframt = 0; atp->lun = lun; atp->nphdl = nphdl; atp->portid = sid; atp->oxid = aep->at_hdr.ox_id; atp->cdb0 = atiop->cdb_io.cdb_bytes[0]; atp->tattr = aep->at_cmnd.fcp_cmnd_task_attribute & FCP_CMND_TASK_ATTR_MASK; atp->state = ATPD_STATE_CAM; ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, tptr->owner, "ATIO7[%x] CDB=0x%x lun %d datalen %u\n", aep->at_rxid, atp->cdb0, lun, atp->orig_datalen); xpt_done((union ccb *)atiop); rls_lun_statep(isp, tptr); return; noresrc: if (atp) { isp_put_atpd(isp, tptr, atp); } ntp = isp_get_ntpd(isp, tptr); if (ntp == NULL) { rls_lun_statep(isp, tptr); isp_endcmd(isp, aep, nphdl, chan, SCSI_STATUS_BUSY, 0); return; } memcpy(ntp->rd.data, aep, QENTRY_LEN); ntp->rd.nt.nt_hba = tptr->restart_queue; tptr->restart_queue = ntp; rls_lun_statep(isp, tptr); } static void isp_handle_platform_ctio(ispsoftc_t *isp, void *arg) { union ccb *ccb; int sentstatus, ok, notify_cam, resid = 0; tstate_t *tptr = NULL; atio_private_data_t *atp = NULL; int bus; uint32_t tval, handle; /* * CTIO handles are 16 bits. * CTIO2 and CTIO7 are 32 bits. */ if (IS_SCSI(isp)) { handle = ((ct_entry_t *)arg)->ct_syshandle; } else { handle = ((ct2_entry_t *)arg)->ct_syshandle; } ccb = isp_find_xs_tgt(isp, handle); if (ccb == NULL) { isp_print_bytes(isp, "null ccb in isp_handle_platform_ctio", QENTRY_LEN, arg); return; } isp_destroy_tgt_handle(isp, handle); bus = XS_CHANNEL(ccb); tptr = get_lun_statep(isp, bus, XS_LUN(ccb)); if (tptr == NULL) { tptr = get_lun_statep(isp, bus, CAM_LUN_WILDCARD); } KASSERT((tptr != NULL), ("cannot get state pointer")); if (isp->isp_nactive) { isp->isp_nactive++; } if (IS_24XX(isp)) { ct7_entry_t *ct = arg; atp = isp_get_atpd(isp, tptr, ct->ct_rxid); if (atp == NULL) { rls_lun_statep(isp, tptr); isp_prt(isp, ISP_LOGERR, "%s: cannot find adjunct for %x after I/O", __func__, ct->ct_rxid); return; } sentstatus = ct->ct_flags & CT7_SENDSTATUS; ok = (ct->ct_nphdl == CT7_OK); if (ok && sentstatus && (ccb->ccb_h.flags & CAM_SEND_SENSE)) { ccb->ccb_h.status |= CAM_SENT_SENSE; } notify_cam = ct->ct_header.rqs_seqno & 0x1; if ((ct->ct_flags & CT7_DATAMASK) != CT7_NO_DATA) { resid = ct->ct_resid; atp->bytes_xfered += (atp->last_xframt - resid); atp->last_xframt = 0; } if (ct->ct_nphdl == CT_HBA_RESET) { ok = 0; notify_cam = 1; sentstatus = 1; ccb->ccb_h.status |= CAM_UNREC_HBA_ERROR; } else if (!ok) { ccb->ccb_h.status |= CAM_REQ_CMP_ERR; } tval = atp->tag; isp_prt(isp, ok? ISP_LOGTDEBUG0 : ISP_LOGWARN, "%s: CTIO7[%x] sts 0x%x flg 0x%x sns %d resid %d %s", __func__, ct->ct_rxid, ct->ct_nphdl, ct->ct_flags, (ccb->ccb_h.status & CAM_SENT_SENSE) != 0, resid, sentstatus? "FIN" : "MID"); atp->state = ATPD_STATE_PDON; /* XXX: should really come after isp_complete_ctio */ } else if (IS_FC(isp)) { ct2_entry_t *ct = arg; atp = isp_get_atpd(isp, tptr, ct->ct_rxid); if (atp == NULL) { rls_lun_statep(isp, tptr); isp_prt(isp, ISP_LOGERR, "%s: cannot find adjunct for %x after I/O", __func__, ct->ct_rxid); return; } sentstatus = ct->ct_flags & CT2_SENDSTATUS; ok = (ct->ct_status & ~QLTM_SVALID) == CT_OK; if (ok && sentstatus && (ccb->ccb_h.flags & CAM_SEND_SENSE)) { ccb->ccb_h.status |= CAM_SENT_SENSE; } notify_cam = ct->ct_header.rqs_seqno & 0x1; if ((ct->ct_flags & CT2_DATAMASK) != CT2_NO_DATA) { resid = ct->ct_resid; atp->bytes_xfered += (atp->last_xframt - resid); atp->last_xframt = 0; } if (ct->ct_status == CT_HBA_RESET) { ok = 0; notify_cam = 1; sentstatus = 1; ccb->ccb_h.status |= CAM_UNREC_HBA_ERROR; } else if (!ok) { ccb->ccb_h.status |= CAM_REQ_CMP_ERR; } isp_prt(isp, ok? ISP_LOGTDEBUG0 : ISP_LOGWARN, "%s: CTIO2[%x] sts 0x%x flg 0x%x sns %d resid %d %s", __func__, ct->ct_rxid, ct->ct_status, ct->ct_flags, (ccb->ccb_h.status & CAM_SENT_SENSE) != 0, resid, sentstatus? "FIN" : "MID"); tval = atp->tag; atp->state = ATPD_STATE_PDON; /* XXX: should really come after isp_complete_ctio */ } else { ct_entry_t *ct = arg; sentstatus = ct->ct_flags & CT_SENDSTATUS; ok = (ct->ct_status & ~QLTM_SVALID) == CT_OK; /* * We *ought* to be able to get back to the original ATIO * here, but for some reason this gets lost. It's just as * well because it's squirrelled away as part of periph * private data. * * We can live without it as long as we continue to use * the auto-replenish feature for CTIOs. */ notify_cam = ct->ct_header.rqs_seqno & 0x1; if (ct->ct_status == (CT_HBA_RESET & 0xff)) { ok = 0; notify_cam = 1; sentstatus = 1; ccb->ccb_h.status |= CAM_UNREC_HBA_ERROR; } else if (!ok) { ccb->ccb_h.status |= CAM_REQ_CMP_ERR; } else if (ct->ct_status & QLTM_SVALID) { char *sp = (char *)ct; sp += CTIO_SENSE_OFFSET; ccb->csio.sense_len = min(sizeof (ccb->csio.sense_data), QLTM_SENSELEN); ISP_MEMCPY(&ccb->csio.sense_data, sp, ccb->csio.sense_len); ccb->ccb_h.status |= CAM_AUTOSNS_VALID; } if ((ct->ct_flags & CT_DATAMASK) != CT_NO_DATA) { resid = ct->ct_resid; } isp_prt(isp, ISP_LOGTDEBUG0, "%s: CTIO[%x] tag %x S_ID 0x%x lun %d sts %x flg %x resid %d %s", __func__, ct->ct_fwhandle, ct->ct_tag_val, ct->ct_iid, ct->ct_lun, ct->ct_status, ct->ct_flags, resid, sentstatus? "FIN" : "MID"); tval = ct->ct_fwhandle; } ccb->csio.resid += resid; /* * We're here either because intermediate data transfers are done * and/or the final status CTIO (which may have joined with a * Data Transfer) is done. * * In any case, for this platform, the upper layers figure out * what to do next, so all we do here is collect status and * pass information along. Any DMA handles have already been * freed. */ if (notify_cam == 0) { isp_prt(isp, ISP_LOGTDEBUG0, " INTER CTIO[0x%x] done", tval); return; } if (tptr) { rls_lun_statep(isp, tptr); } isp_prt(isp, ISP_LOGTDEBUG0, "%s CTIO[0x%x] done", (sentstatus)? " FINAL " : "MIDTERM ", tval); if (!ok && !IS_24XX(isp)) { isp_target_putback_atio(ccb); } else { isp_complete_ctio(ccb); } } static void isp_handle_platform_notify_scsi(ispsoftc_t *isp, in_entry_t *inot) { (void) isp_notify_ack(isp, inot); } static void isp_handle_platform_notify_fc(ispsoftc_t *isp, in_fcentry_t *inp) { int needack = 1; switch (inp->in_status) { case IN_PORT_LOGOUT: /* * XXX: Need to delete this initiator's WWN from the database * XXX: Need to send this LOGOUT upstream */ isp_prt(isp, ISP_LOGWARN, "port logout of S_ID 0x%x", inp->in_iid); break; case IN_PORT_CHANGED: isp_prt(isp, ISP_LOGWARN, "port changed for S_ID 0x%x", inp->in_iid); break; case IN_GLOBAL_LOGO: isp_del_all_wwn_entries(isp, 0); isp_prt(isp, ISP_LOGINFO, "all ports logged out"); break; case IN_ABORT_TASK: { tstate_t *tptr; uint16_t lun; uint32_t loopid; uint64_t wwn; atio_private_data_t *atp; fcportdb_t *lp; struct ccb_immediate_notify *inot = NULL; if (ISP_CAP_SCCFW(isp)) { lun = inp->in_scclun; } else { lun = inp->in_lun; } if (ISP_CAP_2KLOGIN(isp)) { loopid = ((in_fcentry_e_t *)inp)->in_iid; } else { loopid = inp->in_iid; } if (isp_find_pdb_by_loopid(isp, 0, loopid, &lp)) { wwn = lp->port_wwn; } else { wwn = INI_ANY; } tptr = get_lun_statep(isp, 0, lun); if (tptr == NULL) { tptr = get_lun_statep(isp, 0, CAM_LUN_WILDCARD); if (tptr == NULL) { isp_prt(isp, ISP_LOGWARN, "ABORT TASK for lun %u- but no tstate", lun); return; } } atp = isp_get_atpd(isp, tptr, inp->in_seqid); if (atp) { inot = (struct ccb_immediate_notify *) SLIST_FIRST(&tptr->inots); isp_prt(isp, ISP_LOGTDEBUG0, "ABORT TASK RX_ID %x WWN 0x%016llx state %d", inp->in_seqid, (unsigned long long) wwn, atp->state); if (inot) { tptr->inot_count--; SLIST_REMOVE_HEAD(&tptr->inots, sim_links.sle); ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, inot->ccb_h.path, "%s: Take FREE INOT count now %d\n", __func__, tptr->inot_count); } else { ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, tptr->owner, "out of INOT structures\n"); } } else { ISP_PATH_PRT(isp, ISP_LOGWARN, tptr->owner, "abort task RX_ID %x from wwn 0x%016llx, state unknown\n", inp->in_seqid, wwn); } if (inot) { isp_notify_t tmp, *nt = &tmp; ISP_MEMZERO(nt, sizeof (isp_notify_t)); nt->nt_hba = isp; nt->nt_tgt = FCPARAM(isp, 0)->isp_wwpn; nt->nt_wwn = wwn; nt->nt_nphdl = loopid; nt->nt_sid = PORT_ANY; nt->nt_did = PORT_ANY; nt->nt_lun = lun; nt->nt_need_ack = 1; nt->nt_channel = 0; nt->nt_ncode = NT_ABORT_TASK; nt->nt_lreserved = inot; isp_handle_platform_target_tmf(isp, nt); needack = 0; } rls_lun_statep(isp, tptr); break; } default: break; } if (needack) { (void) isp_notify_ack(isp, inp); } } static void isp_handle_platform_notify_24xx(ispsoftc_t *isp, in_fcentry_24xx_t *inot) { uint16_t nphdl; uint32_t portid; fcportdb_t *lp; uint8_t *ptr = NULL; uint64_t wwn; nphdl = inot->in_nphdl; if (nphdl != NIL_HANDLE) { portid = inot->in_portid_hi << 16 | inot->in_portid_lo; } else { portid = PORT_ANY; } switch (inot->in_status) { case IN24XX_ELS_RCVD: { char buf[16], *msg; int chan = ISP_GET_VPIDX(isp, inot->in_vpidx); /* * Note that we're just getting notification that an ELS was received * (possibly with some associated information sent upstream). This is * *not* the same as being given the ELS frame to accept or reject. */ switch (inot->in_status_subcode) { case LOGO: msg = "LOGO"; if (ISP_FW_NEWER_THAN(isp, 4, 0, 25)) { ptr = (uint8_t *)inot; /* point to unswizzled entry! */ wwn = (((uint64_t) ptr[IN24XX_LOGO_WWPN_OFF]) << 56) | (((uint64_t) ptr[IN24XX_LOGO_WWPN_OFF+1]) << 48) | (((uint64_t) ptr[IN24XX_LOGO_WWPN_OFF+2]) << 40) | (((uint64_t) ptr[IN24XX_LOGO_WWPN_OFF+3]) << 32) | (((uint64_t) ptr[IN24XX_LOGO_WWPN_OFF+4]) << 24) | (((uint64_t) ptr[IN24XX_LOGO_WWPN_OFF+5]) << 16) | (((uint64_t) ptr[IN24XX_LOGO_WWPN_OFF+6]) << 8) | (((uint64_t) ptr[IN24XX_LOGO_WWPN_OFF+7])); } else { wwn = INI_ANY; } isp_del_wwn_entry(isp, chan, wwn, nphdl, portid); break; case PRLO: msg = "PRLO"; break; case PLOGI: case PRLI: /* * Treat PRLI the same as PLOGI and make a database entry for it. */ if (inot->in_status_subcode == PLOGI) msg = "PLOGI"; else msg = "PRLI"; if (ISP_FW_NEWER_THAN(isp, 4, 0, 25)) { ptr = (uint8_t *)inot; /* point to unswizzled entry! */ wwn = (((uint64_t) ptr[IN24XX_PLOGI_WWPN_OFF]) << 56) | (((uint64_t) ptr[IN24XX_PLOGI_WWPN_OFF+1]) << 48) | (((uint64_t) ptr[IN24XX_PLOGI_WWPN_OFF+2]) << 40) | (((uint64_t) ptr[IN24XX_PLOGI_WWPN_OFF+3]) << 32) | (((uint64_t) ptr[IN24XX_PLOGI_WWPN_OFF+4]) << 24) | (((uint64_t) ptr[IN24XX_PLOGI_WWPN_OFF+5]) << 16) | (((uint64_t) ptr[IN24XX_PLOGI_WWPN_OFF+6]) << 8) | (((uint64_t) ptr[IN24XX_PLOGI_WWPN_OFF+7])); } else { wwn = INI_NONE; } isp_add_wwn_entry(isp, chan, wwn, nphdl, portid); break; case PDISC: msg = "PDISC"; break; case ADISC: msg = "ADISC"; break; default: ISP_SNPRINTF(buf, sizeof (buf), "ELS 0x%x", inot->in_status_subcode); msg = buf; break; } if (inot->in_flags & IN24XX_FLAG_PUREX_IOCB) { isp_prt(isp, ISP_LOGERR, "%s Chan %d ELS N-port handle %x PortID 0x%06x marked as needing a PUREX response", msg, chan, nphdl, portid); break; } isp_prt(isp, ISP_LOGTDEBUG0, "%s Chan %d ELS N-port handle %x PortID 0x%06x RX_ID 0x%x OX_ID 0x%x", msg, chan, nphdl, portid, inot->in_rxid, inot->in_oxid); (void) isp_notify_ack(isp, inot); break; } case IN24XX_PORT_LOGOUT: ptr = "PORT LOGOUT"; if (isp_find_pdb_by_loopid(isp, ISP_GET_VPIDX(isp, inot->in_vpidx), nphdl, &lp)) { isp_del_wwn_entry(isp, ISP_GET_VPIDX(isp, inot->in_vpidx), lp->port_wwn, nphdl, lp->portid); } /* FALLTHROUGH */ case IN24XX_PORT_CHANGED: if (ptr == NULL) { ptr = "PORT CHANGED"; } /* FALLTHROUGH */ case IN24XX_LIP_RESET: if (ptr == NULL) { ptr = "LIP RESET"; } isp_prt(isp, ISP_LOGINFO, "Chan %d %s (sub-status 0x%x) for N-port handle 0x%x", ISP_GET_VPIDX(isp, inot->in_vpidx), ptr, inot->in_status_subcode, nphdl); /* * All subcodes here are irrelevant. What is relevant * is that we need to terminate all active commands from * this initiator (known by N-port handle). */ /* XXX IMPLEMENT XXX */ (void) isp_notify_ack(isp, inot); break; case IN24XX_LINK_RESET: case IN24XX_LINK_FAILED: case IN24XX_SRR_RCVD: default: (void) isp_notify_ack(isp, inot); break; } } static int isp_handle_platform_target_notify_ack(ispsoftc_t *isp, isp_notify_t *mp) { if (isp->isp_state != ISP_RUNSTATE) { isp_prt(isp, ISP_LOGTINFO, "Notify Code 0x%x (qevalid=%d) acked- h/w not ready (dropping)", mp->nt_ncode, mp->nt_lreserved != NULL); return (0); } /* * This case is for a Task Management Function, which shows up as an ATIO7 entry. */ if (IS_24XX(isp) && mp->nt_lreserved && ((isphdr_t *)mp->nt_lreserved)->rqs_entry_type == RQSTYPE_ATIO) { ct7_entry_t local, *cto = &local; at7_entry_t *aep = (at7_entry_t *)mp->nt_lreserved; fcportdb_t *lp; uint32_t sid; uint16_t nphdl; sid = (aep->at_hdr.s_id[0] << 16) | (aep->at_hdr.s_id[1] << 8) | aep->at_hdr.s_id[2]; if (isp_find_pdb_by_sid(isp, mp->nt_channel, sid, &lp)) { nphdl = lp->handle; } else { nphdl = NIL_HANDLE; } ISP_MEMZERO(&local, sizeof (local)); cto->ct_header.rqs_entry_type = RQSTYPE_CTIO7; cto->ct_header.rqs_entry_count = 1; cto->ct_nphdl = nphdl; cto->ct_rxid = aep->at_rxid; cto->ct_vpidx = mp->nt_channel; cto->ct_iid_lo = sid; cto->ct_iid_hi = sid >> 16; cto->ct_oxid = aep->at_hdr.ox_id; cto->ct_flags = CT7_SENDSTATUS|CT7_NOACK|CT7_NO_DATA|CT7_FLAG_MODE1; cto->ct_flags |= (aep->at_ta_len >> 12) << CT7_TASK_ATTR_SHIFT; return (isp_target_put_entry(isp, &local)); } /* * This case is for a responding to an ABTS frame */ if (IS_24XX(isp) && mp->nt_lreserved && ((isphdr_t *)mp->nt_lreserved)->rqs_entry_type == RQSTYPE_ABTS_RCVD) { /* * Overload nt_need_ack here to mark whether we've terminated the associated command. */ if (mp->nt_need_ack) { uint8_t storage[QENTRY_LEN]; ct7_entry_t *cto = (ct7_entry_t *) storage; abts_t *abts = (abts_t *)mp->nt_lreserved; ISP_MEMZERO(cto, sizeof (ct7_entry_t)); isp_prt(isp, ISP_LOGTDEBUG0, "%s: [%x] terminating after ABTS received", __func__, abts->abts_rxid_task); cto->ct_header.rqs_entry_type = RQSTYPE_CTIO7; cto->ct_header.rqs_entry_count = 1; cto->ct_nphdl = mp->nt_nphdl; cto->ct_rxid = abts->abts_rxid_task; cto->ct_iid_lo = mp->nt_sid; cto->ct_iid_hi = mp->nt_sid >> 16; cto->ct_oxid = abts->abts_ox_id; cto->ct_vpidx = mp->nt_channel; cto->ct_flags = CT7_NOACK|CT7_TERMINATE; if (isp_target_put_entry(isp, cto)) { return (ENOMEM); } mp->nt_need_ack = 0; } if (isp_acknak_abts(isp, mp->nt_lreserved, 0) == ENOMEM) { return (ENOMEM); } else { return (0); } } /* * Handle logout cases here */ if (mp->nt_ncode == NT_GLOBAL_LOGOUT) { isp_del_all_wwn_entries(isp, mp->nt_channel); } if (mp->nt_ncode == NT_LOGOUT) { if (!IS_2100(isp) && IS_FC(isp)) { isp_del_wwn_entries(isp, mp); } } /* * General purpose acknowledgement */ if (mp->nt_need_ack) { isp_prt(isp, ISP_LOGTINFO, "Notify Code 0x%x (qevalid=%d) being acked", mp->nt_ncode, mp->nt_lreserved != NULL); return (isp_notify_ack(isp, mp->nt_lreserved)); } return (0); } /* * Handle task management functions. * * We show up here with a notify structure filled out. * * The nt_lreserved tag points to the original queue entry */ static void isp_handle_platform_target_tmf(ispsoftc_t *isp, isp_notify_t *notify) { tstate_t *tptr; fcportdb_t *lp; struct ccb_immediate_notify *inot; inot_private_data_t *ntp = NULL; lun_id_t lun; isp_prt(isp, ISP_LOGTDEBUG0, "%s: code 0x%x sid 0x%x tagval 0x%016llx chan %d lun 0x%x", __func__, notify->nt_ncode, notify->nt_sid, (unsigned long long) notify->nt_tagval, notify->nt_channel, notify->nt_lun); /* * NB: This assignment is necessary because of tricky type conversion. * XXX: This is tricky and I need to check this. If the lun isn't known * XXX: for the task management function, it does not of necessity follow * XXX: that it should go up stream to the wildcard listener. */ if (notify->nt_lun == LUN_ANY) { lun = CAM_LUN_WILDCARD; } else { lun = notify->nt_lun; } tptr = get_lun_statep(isp, notify->nt_channel, lun); if (tptr == NULL) { tptr = get_lun_statep(isp, notify->nt_channel, CAM_LUN_WILDCARD); if (tptr == NULL) { isp_prt(isp, ISP_LOGWARN, "%s: no state pointer found for chan %d lun 0x%x", __func__, notify->nt_channel, lun); goto bad; } } inot = (struct ccb_immediate_notify *) SLIST_FIRST(&tptr->inots); if (inot == NULL) { isp_prt(isp, ISP_LOGWARN, "%s: out of immediate notify structures for chan %d lun 0x%x", __func__, notify->nt_channel, lun); goto bad; } if (isp_find_pdb_by_sid(isp, notify->nt_channel, notify->nt_sid, &lp) == 0) { inot->initiator_id = CAM_TARGET_WILDCARD; } else { inot->initiator_id = lp->handle; } inot->seq_id = notify->nt_tagval; inot->tag_id = notify->nt_tagval >> 32; switch (notify->nt_ncode) { case NT_ABORT_TASK: isp_target_mark_aborted_early(isp, tptr, inot->tag_id); inot->arg = MSG_ABORT_TASK; break; case NT_ABORT_TASK_SET: isp_target_mark_aborted_early(isp, tptr, TAG_ANY); inot->arg = MSG_ABORT_TASK_SET; break; case NT_CLEAR_ACA: inot->arg = MSG_CLEAR_ACA; break; case NT_CLEAR_TASK_SET: inot->arg = MSG_CLEAR_TASK_SET; break; case NT_LUN_RESET: inot->arg = MSG_LOGICAL_UNIT_RESET; break; case NT_TARGET_RESET: inot->arg = MSG_TARGET_RESET; break; default: isp_prt(isp, ISP_LOGWARN, "%s: unknown TMF code 0x%x for chan %d lun 0x%x", __func__, notify->nt_ncode, notify->nt_channel, lun); goto bad; } ntp = isp_get_ntpd(isp, tptr); if (ntp == NULL) { isp_prt(isp, ISP_LOGWARN, "%s: out of inotify private structures", __func__); goto bad; } ISP_MEMCPY(&ntp->rd.nt, notify, sizeof (isp_notify_t)); if (notify->nt_lreserved) { ISP_MEMCPY(&ntp->rd.data, notify->nt_lreserved, QENTRY_LEN); ntp->rd.nt.nt_lreserved = &ntp->rd.data; } ntp->rd.seq_id = notify->nt_tagval; ntp->rd.tag_id = notify->nt_tagval >> 32; tptr->inot_count--; SLIST_REMOVE_HEAD(&tptr->inots, sim_links.sle); rls_lun_statep(isp, tptr); ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, inot->ccb_h.path, "%s: Take FREE INOT count now %d\n", __func__, tptr->inot_count); inot->ccb_h.status = CAM_MESSAGE_RECV; xpt_done((union ccb *)inot); return; bad: if (tptr) { rls_lun_statep(isp, tptr); } if (notify->nt_need_ack && notify->nt_lreserved) { if (((isphdr_t *)notify->nt_lreserved)->rqs_entry_type == RQSTYPE_ABTS_RCVD) { (void) isp_acknak_abts(isp, notify->nt_lreserved, ENOMEM); } else { (void) isp_notify_ack(isp, notify->nt_lreserved); } } } /* * Find the associated private data and mark it as dead so * we don't try to work on it any further. */ static void isp_target_mark_aborted(ispsoftc_t *isp, union ccb *ccb) { tstate_t *tptr; atio_private_data_t *atp; union ccb *accb = ccb->cab.abort_ccb; tptr = get_lun_statep(isp, XS_CHANNEL(accb), XS_LUN(accb)); if (tptr == NULL) { tptr = get_lun_statep(isp, XS_CHANNEL(accb), CAM_LUN_WILDCARD); if (tptr == NULL) { ccb->ccb_h.status = CAM_REQ_INVALID; return; } } atp = isp_get_atpd(isp, tptr, accb->atio.tag_id); if (atp == NULL) { ccb->ccb_h.status = CAM_REQ_INVALID; } else { atp->dead = 1; ccb->ccb_h.status = CAM_REQ_CMP; } rls_lun_statep(isp, tptr); } static void isp_target_mark_aborted_early(ispsoftc_t *isp, tstate_t *tptr, uint32_t tag_id) { atio_private_data_t *atp; inot_private_data_t *restart_queue = tptr->restart_queue; /* * First, clean any commands pending restart */ tptr->restart_queue = NULL; while (restart_queue) { uint32_t this_tag_id; inot_private_data_t *ntp = restart_queue; restart_queue = ntp->rd.nt.nt_hba; if (IS_24XX(isp)) { this_tag_id = ((at7_entry_t *)ntp->rd.data)->at_rxid; } else { this_tag_id = ((at2_entry_t *)ntp->rd.data)->at_rxid; } if ((uint64_t)tag_id == TAG_ANY || tag_id == this_tag_id) { isp_put_ntpd(isp, tptr, ntp); } else { ntp->rd.nt.nt_hba = tptr->restart_queue; tptr->restart_queue = ntp; } } /* * Now mark other ones dead as well. */ for (atp = tptr->atpool; atp < &tptr->atpool[ATPDPSIZE]; atp++) { if ((uint64_t)tag_id == TAG_ANY || atp->tag == tag_id) { atp->dead = 1; } } } #ifdef ISP_INTERNAL_TARGET // #define ISP_FORCE_TIMEOUT 1 // #define ISP_TEST_WWNS 1 // #define ISP_TEST_SEPARATE_STATUS 1 #define ccb_data_offset ppriv_field0 #define ccb_atio ppriv_ptr1 #define ccb_inot ppriv_ptr1 #define MAX_ISP_TARG_TRANSFER (2 << 20) #define NISP_TARG_CMDS 1024 #define NISP_TARG_NOTIFIES 1024 #define DISK_SHIFT 9 #define JUNK_SIZE 256 #ifndef VERIFY_10 #define VERIFY_10 0x2f #endif TAILQ_HEAD(ccb_queue, ccb_hdr); extern u_int vm_kmem_size; static int ca; static uint32_t disk_size; static uint8_t *disk_data = NULL; static uint8_t *junk_data; static MALLOC_DEFINE(M_ISPTARG, "ISPTARG", "ISP TARGET data"); struct isptarg_softc { /* CCBs (CTIOs, ATIOs, INOTs) pending on the controller */ struct ccb_queue work_queue; struct ccb_queue rework_queue; struct ccb_queue running_queue; struct ccb_queue inot_queue; struct cam_periph *periph; struct cam_path *path; ispsoftc_t *isp; }; static periph_ctor_t isptargctor; static periph_dtor_t isptargdtor; static periph_start_t isptargstart; static periph_init_t isptarginit; static void isptarg_done(struct cam_periph *, union ccb *); static void isptargasync(void *, u_int32_t, struct cam_path *, void *); static int isptarg_rwparm(uint8_t *, uint8_t *, uint64_t, uint32_t, uint8_t **, uint32_t *, int *); static struct periph_driver isptargdriver = { isptarginit, "isptarg", TAILQ_HEAD_INITIALIZER(isptargdriver.units), /* generation */ 0 }; static void isptarginit(void) { } static void isptargnotify(ispsoftc_t *isp, union ccb *iccb, struct ccb_immediate_notify *inot) { struct ccb_notify_acknowledge *ack = &iccb->cna2; ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, inot->ccb_h.path, "%s: [0x%x] immediate notify for 0x%x from 0x%x status 0x%x arg 0x%x\n", __func__, inot->tag_id, inot->initiator_id, inot->seq_id, inot->ccb_h.status, inot->arg); ack->ccb_h.func_code = XPT_NOTIFY_ACKNOWLEDGE; ack->ccb_h.flags = 0; ack->ccb_h.retry_count = 0; ack->ccb_h.cbfcnp = isptarg_done; ack->ccb_h.timeout = 0; ack->ccb_h.ccb_inot = inot; ack->tag_id = inot->tag_id; ack->seq_id = inot->seq_id; ack->initiator_id = inot->initiator_id; xpt_action(iccb); } static void isptargstart(struct cam_periph *periph, union ccb *iccb) { const uint8_t niliqd[SHORT_INQUIRY_LENGTH] = { 0x7f, 0x0, 0x5, 0x2, 32, 0, 0, 0x32, 'F', 'R', 'E', 'E', 'B', 'S', 'D', ' ', 'S', 'C', 'S', 'I', ' ', 'N', 'U', 'L', 'L', ' ', 'D', 'E', 'V', 'I', 'C', 'E', '0', '0', '0', '1' }; const uint8_t iqd[SHORT_INQUIRY_LENGTH] = { 0, 0x0, 0x5, 0x2, 32, 0, 0, 0x32, 'F', 'R', 'E', 'E', 'B', 'S', 'D', ' ', 'S', 'C', 'S', 'I', ' ', 'M', 'E', 'M', 'O', 'R', 'Y', ' ', 'D', 'I', 'S', 'K', '0', '0', '0', '1' }; int i, more = 0, last; struct isptarg_softc *softc = periph->softc; struct ccb_scsiio *csio; lun_id_t return_lun; struct ccb_accept_tio *atio; uint8_t *cdb, *ptr, status; uint8_t *data_ptr; uint32_t data_len, flags; struct ccb_hdr *ccbh; mtx_assert(periph->sim->mtx, MA_OWNED); ISP_PATH_PRT(softc->isp, ISP_LOGTDEBUG0, iccb->ccb_h.path, "%s: function code 0x%x INOTQ=%c WORKQ=%c REWORKQ=%c\n", __func__, iccb->ccb_h.func_code, TAILQ_FIRST(&softc->inot_queue)? 'y' : 'n', TAILQ_FIRST(&softc->work_queue)? 'y' : 'n', TAILQ_FIRST(&softc->rework_queue)? 'y' : 'n'); /* * Check for immediate notifies first */ ccbh = TAILQ_FIRST(&softc->inot_queue); if (ccbh) { TAILQ_REMOVE(&softc->inot_queue, ccbh, periph_links.tqe); if (TAILQ_FIRST(&softc->inot_queue) || TAILQ_FIRST(&softc->work_queue) || TAILQ_FIRST(&softc->rework_queue)) { xpt_schedule(periph, 1); } isptargnotify(softc->isp, iccb, (struct ccb_immediate_notify *)ccbh); return; } /* * Check the rework (continuation) work queue first. */ ccbh = TAILQ_FIRST(&softc->rework_queue); if (ccbh) { atio = (struct ccb_accept_tio *)ccbh; TAILQ_REMOVE(&softc->rework_queue, ccbh, periph_links.tqe); more = TAILQ_FIRST(&softc->work_queue) || TAILQ_FIRST(&softc->rework_queue); } else { ccbh = TAILQ_FIRST(&softc->work_queue); if (ccbh == NULL) { ISP_PATH_PRT(softc->isp, ISP_LOGTDEBUG0, iccb->ccb_h.path, "%s: woken up but no work?\n", __func__); xpt_release_ccb(iccb); return; } atio = (struct ccb_accept_tio *)ccbh; TAILQ_REMOVE(&softc->work_queue, ccbh, periph_links.tqe); more = TAILQ_FIRST(&softc->work_queue) != NULL; atio->ccb_h.ccb_data_offset = 0; } if (atio->tag_id == 0xffffffff || atio->ccb_h.func_code != XPT_ACCEPT_TARGET_IO) { panic("BAD ATIO"); } data_ptr = NULL; data_len = 0; csio = &iccb->csio; status = SCSI_STATUS_OK; flags = CAM_SEND_STATUS; memset(&atio->sense_data, 0, sizeof (atio->sense_data)); cdb = atio->cdb_io.cdb_bytes; ISP_PATH_PRT(softc->isp, ISP_LOGTDEBUG0, ccbh->path, "%s: [0x%x] processing ATIO from 0x%x CDB=0x%x data_offset=%u\n", __func__, atio->tag_id, atio->init_id, cdb[0], atio->ccb_h.ccb_data_offset); return_lun = XS_LUN(atio); if (return_lun != 0) { xpt_print(atio->ccb_h.path, "[0x%x] Non-Zero Lun %d: cdb0=0x%x\n", atio->tag_id, return_lun, cdb[0]); if (cdb[0] != INQUIRY && cdb[0] != REPORT_LUNS && cdb[0] != REQUEST_SENSE) { status = SCSI_STATUS_CHECK_COND; atio->sense_data.error_code = SSD_ERRCODE_VALID|SSD_CURRENT_ERROR|SSD_KEY_ILLEGAL_REQUEST; atio->sense_data.add_sense_code = 0x25; atio->sense_data.add_sense_code_qual = 0x0; atio->sense_len = sizeof (atio->sense_data); } return_lun = CAM_LUN_WILDCARD; } switch (cdb[0]) { case REQUEST_SENSE: flags |= CAM_DIR_IN; data_len = sizeof (atio->sense_data); junk_data[0] = SSD_ERRCODE_VALID|SSD_CURRENT_ERROR|SSD_KEY_NO_SENSE; memset(junk_data+1, 0, data_len-1); if (data_len > cdb[4]) { data_len = cdb[4]; } if (data_len) { data_ptr = junk_data; } break; case READ_6: case READ_10: case READ_12: case READ_16: if (isptarg_rwparm(cdb, disk_data, disk_size, atio->ccb_h.ccb_data_offset, &data_ptr, &data_len, &last)) { status = SCSI_STATUS_CHECK_COND; atio->sense_data.error_code = SSD_ERRCODE_VALID|SSD_CURRENT_ERROR|SSD_KEY_UNIT_ATTENTION; atio->sense_data.add_sense_code = 0x5; atio->sense_data.add_sense_code_qual = 0x24; atio->sense_len = sizeof (atio->sense_data); } else { #ifdef ISP_FORCE_TIMEOUT { static int foo; if (foo++ == 500) { if (more) { xpt_schedule(periph, 1); } foo = 0; return; } } #endif #ifdef ISP_TEST_SEPARATE_STATUS if (last && data_len) { last = 0; } #endif if (last == 0) { flags &= ~CAM_SEND_STATUS; } if (data_len) { atio->ccb_h.ccb_data_offset += data_len; flags |= CAM_DIR_IN; } else { flags |= CAM_DIR_NONE; } } break; case WRITE_6: case WRITE_10: case WRITE_12: case WRITE_16: if (isptarg_rwparm(cdb, disk_data, disk_size, atio->ccb_h.ccb_data_offset, &data_ptr, &data_len, &last)) { status = SCSI_STATUS_CHECK_COND; atio->sense_data.error_code = SSD_ERRCODE_VALID|SSD_CURRENT_ERROR|SSD_KEY_UNIT_ATTENTION; atio->sense_data.add_sense_code = 0x5; atio->sense_data.add_sense_code_qual = 0x24; atio->sense_len = sizeof (atio->sense_data); } else { #ifdef ISP_FORCE_TIMEOUT { static int foo; if (foo++ == 500) { if (more) { xpt_schedule(periph, 1); } foo = 0; return; } } #endif #ifdef ISP_TEST_SEPARATE_STATUS if (last && data_len) { last = 0; } #endif if (last == 0) { flags &= ~CAM_SEND_STATUS; } if (data_len) { atio->ccb_h.ccb_data_offset += data_len; flags |= CAM_DIR_OUT; } else { flags |= CAM_DIR_NONE; } } break; case INQUIRY: flags |= CAM_DIR_IN; if (cdb[1] || cdb[2] || cdb[3]) { status = SCSI_STATUS_CHECK_COND; atio->sense_data.error_code = SSD_ERRCODE_VALID|SSD_CURRENT_ERROR|SSD_KEY_UNIT_ATTENTION; atio->sense_data.add_sense_code = 0x5; atio->sense_data.add_sense_code_qual = 0x20; atio->sense_len = sizeof (atio->sense_data); break; } data_len = sizeof (iqd); if (data_len > cdb[4]) { data_len = cdb[4]; } if (data_len) { if (XS_LUN(iccb) != 0) { memcpy(junk_data, niliqd, sizeof (iqd)); } else { memcpy(junk_data, iqd, sizeof (iqd)); } data_ptr = junk_data; } break; case TEST_UNIT_READY: flags |= CAM_DIR_NONE; if (ca) { ca = 0; status = SCSI_STATUS_CHECK_COND; atio->sense_data.error_code = SSD_ERRCODE_VALID|SSD_CURRENT_ERROR|SSD_KEY_UNIT_ATTENTION; atio->sense_data.add_sense_code = 0x28; atio->sense_data.add_sense_code_qual = 0x0; atio->sense_len = sizeof (atio->sense_data); } break; case SYNCHRONIZE_CACHE: case START_STOP: case RESERVE: case RELEASE: case VERIFY_10: flags |= CAM_DIR_NONE; break; case READ_CAPACITY: flags |= CAM_DIR_IN; if (cdb[2] || cdb[3] || cdb[4] || cdb[5]) { status = SCSI_STATUS_CHECK_COND; atio->sense_data.error_code = SSD_ERRCODE_VALID|SSD_CURRENT_ERROR|SSD_KEY_UNIT_ATTENTION; atio->sense_data.add_sense_code = 0x5; atio->sense_data.add_sense_code_qual = 0x24; atio->sense_len = sizeof (atio->sense_data); break; } if (cdb[8] & 0x1) { /* PMI */ junk_data[0] = 0xff; junk_data[1] = 0xff; junk_data[2] = 0xff; junk_data[3] = 0xff; } else { uint64_t last_blk = (disk_size >> DISK_SHIFT) - 1; if (last_blk < 0xffffffffULL) { junk_data[0] = (last_blk >> 24) & 0xff; junk_data[1] = (last_blk >> 16) & 0xff; junk_data[2] = (last_blk >> 8) & 0xff; junk_data[3] = (last_blk) & 0xff; } else { junk_data[0] = 0xff; junk_data[1] = 0xff; junk_data[2] = 0xff; junk_data[3] = 0xff; } } junk_data[4] = ((1 << DISK_SHIFT) >> 24) & 0xff; junk_data[5] = ((1 << DISK_SHIFT) >> 16) & 0xff; junk_data[6] = ((1 << DISK_SHIFT) >> 8) & 0xff; junk_data[7] = ((1 << DISK_SHIFT)) & 0xff; data_ptr = junk_data; data_len = 8; break; case REPORT_LUNS: flags |= CAM_DIR_IN; memset(junk_data, 0, JUNK_SIZE); junk_data[0] = (1 << 3) >> 24; junk_data[1] = (1 << 3) >> 16; junk_data[2] = (1 << 3) >> 8; junk_data[3] = (1 << 3); ptr = NULL; for (i = 0; i < 1; i++) { ptr = &junk_data[8 + (1 << 3)]; if (i >= 256) { ptr[0] = 0x40 | ((i >> 8) & 0x3f); } ptr[1] = i; } data_ptr = junk_data; data_len = (ptr + 8) - junk_data; break; default: flags |= CAM_DIR_NONE; status = SCSI_STATUS_CHECK_COND; atio->sense_data.error_code = SSD_ERRCODE_VALID|SSD_CURRENT_ERROR|SSD_KEY_UNIT_ATTENTION; atio->sense_data.add_sense_code = 0x5; atio->sense_data.add_sense_code_qual = 0x20; atio->sense_len = sizeof (atio->sense_data); break; } /* * If we are done with the transaction, tell the * controller to send status and perform a CMD_CMPLT. * If we have associated sense data, see if we can * send that too. */ if (status == SCSI_STATUS_CHECK_COND) { flags |= CAM_SEND_SENSE; csio->sense_len = atio->sense_len; csio->sense_data = atio->sense_data; flags &= ~CAM_DIR_MASK; data_len = 0; data_ptr = NULL; } cam_fill_ctio(csio, 0, isptarg_done, flags, MSG_SIMPLE_Q_TAG, atio->tag_id, atio->init_id, status, data_ptr, data_len, 0); iccb->ccb_h.target_id = atio->ccb_h.target_id; iccb->ccb_h.target_lun = return_lun; iccb->ccb_h.ccb_atio = atio; xpt_action(iccb); if ((atio->ccb_h.status & CAM_DEV_QFRZN) != 0) { cam_release_devq(periph->path, 0, 0, 0, 0); atio->ccb_h.status &= ~CAM_DEV_QFRZN; } if (more) { xpt_schedule(periph, 1); } } static cam_status isptargctor(struct cam_periph *periph, void *arg) { struct isptarg_softc *softc; softc = (struct isptarg_softc *)arg; periph->softc = softc; softc->periph = periph; softc->path = periph->path; ISP_PATH_PRT(softc->isp, ISP_LOGTDEBUG0, periph->path, "%s called\n", __func__); return (CAM_REQ_CMP); } static void isptargdtor(struct cam_periph *periph) { struct isptarg_softc *softc; softc = (struct isptarg_softc *)periph->softc; ISP_PATH_PRT(softc->isp, ISP_LOGTDEBUG0, periph->path, "%s called\n", __func__); softc->periph = NULL; softc->path = NULL; periph->softc = NULL; } static void isptarg_done(struct cam_periph *periph, union ccb *ccb) { struct isptarg_softc *softc; ispsoftc_t *isp; struct ccb_accept_tio *atio; struct ccb_immediate_notify *inot; cam_status status; softc = (struct isptarg_softc *)periph->softc; isp = softc->isp; status = ccb->ccb_h.status & CAM_STATUS_MASK; switch (ccb->ccb_h.func_code) { case XPT_ACCEPT_TARGET_IO: atio = (struct ccb_accept_tio *) ccb; ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, ccb->ccb_h.path, "[0x%x] ATIO seen in %s\n", atio->tag_id, __func__); TAILQ_INSERT_TAIL(&softc->work_queue, &ccb->ccb_h, periph_links.tqe); xpt_schedule(periph, 1); break; case XPT_IMMEDIATE_NOTIFY: inot = (struct ccb_immediate_notify *) ccb; ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, ccb->ccb_h.path, "[0x%x] INOT for 0x%x seen in %s\n", inot->tag_id, inot->seq_id, __func__); TAILQ_INSERT_TAIL(&softc->inot_queue, &ccb->ccb_h, periph_links.tqe); xpt_schedule(periph, 1); break; case XPT_CONT_TARGET_IO: if ((ccb->ccb_h.status & CAM_DEV_QFRZN) != 0) { cam_release_devq(ccb->ccb_h.path, 0, 0, 0, 0); ccb->ccb_h.status &= ~CAM_DEV_QFRZN; } atio = ccb->ccb_h.ccb_atio; if ((ccb->ccb_h.status & CAM_STATUS_MASK) != CAM_REQ_CMP) { cam_error_print(ccb, CAM_ESF_ALL, CAM_EPF_ALL); xpt_action((union ccb *)atio); } else if ((ccb->ccb_h.flags & CAM_SEND_STATUS) == 0) { ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, ccb->ccb_h.path, "[0x%x] MID CTIO seen in %s\n", atio->tag_id, __func__); TAILQ_INSERT_TAIL(&softc->rework_queue, &atio->ccb_h, periph_links.tqe); xpt_schedule(periph, 1); } else { ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, ccb->ccb_h.path, "[0x%x] FINAL CTIO seen in %s\n", atio->tag_id, __func__); xpt_action((union ccb *)atio); } xpt_release_ccb(ccb); break; case XPT_NOTIFY_ACKNOWLEDGE: if ((ccb->ccb_h.status & CAM_DEV_QFRZN) != 0) { cam_release_devq(ccb->ccb_h.path, 0, 0, 0, 0); ccb->ccb_h.status &= ~CAM_DEV_QFRZN; } inot = ccb->ccb_h.ccb_inot; ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, inot->ccb_h.path, "[0x%x] recycle notify for tag 0x%x\n", inot->tag_id, inot->seq_id); xpt_release_ccb(ccb); xpt_action((union ccb *)inot); break; default: xpt_print(ccb->ccb_h.path, "unexpected code 0x%x\n", ccb->ccb_h.func_code); break; } } static void isptargasync(void *callback_arg, u_int32_t code, struct cam_path *path, void *arg) { struct ac_contract *acp = arg; struct ac_device_changed *fc = (struct ac_device_changed *) acp->contract_data; if (code != AC_CONTRACT) { return; } xpt_print(path, "0x%016llx Port ID 0x%06x %s\n", (unsigned long long) fc->wwpn, fc->port, fc->arrived? "arrived" : "departed"); } static void isp_target_thread(ispsoftc_t *isp, int chan) { union ccb *ccb = NULL; int i; void *wchan; cam_status status; struct isptarg_softc *softc = NULL; struct cam_periph *periph = NULL, *wperiph = NULL; struct cam_path *path, *wpath; struct cam_sim *sim; if (disk_data == NULL) { disk_size = roundup2(vm_kmem_size >> 1, (1ULL << 20)); if (disk_size < (50 << 20)) { disk_size = 50 << 20; } disk_data = malloc(disk_size, M_ISPTARG, M_WAITOK | M_ZERO); if (disk_data == NULL) { isp_prt(isp, ISP_LOGERR, "%s: could not allocate disk data", __func__); goto out; } isp_prt(isp, ISP_LOGINFO, "allocated a %ju MiB disk", (uintmax_t) (disk_size >> 20)); } junk_data = malloc(JUNK_SIZE, M_ISPTARG, M_WAITOK | M_ZERO); if (junk_data == NULL) { isp_prt(isp, ISP_LOGERR, "%s: could not allocate junk", __func__); goto out; } softc = malloc(sizeof (*softc), M_ISPTARG, M_WAITOK | M_ZERO); if (softc == NULL) { isp_prt(isp, ISP_LOGERR, "%s: could not allocate softc", __func__); goto out; } TAILQ_INIT(&softc->work_queue); TAILQ_INIT(&softc->rework_queue); TAILQ_INIT(&softc->running_queue); TAILQ_INIT(&softc->inot_queue); softc->isp = isp; periphdriver_register(&isptargdriver); ISP_GET_PC(isp, chan, sim, sim); ISP_GET_PC(isp, chan, path, path); status = xpt_create_path_unlocked(&wpath, NULL, cam_sim_path(sim), CAM_TARGET_WILDCARD, CAM_LUN_WILDCARD); if (status != CAM_REQ_CMP) { isp_prt(isp, ISP_LOGERR, "%s: could not allocate wildcard path", __func__); return; } status = xpt_create_path_unlocked(&path, NULL, cam_sim_path(sim), 0, 0); if (status != CAM_REQ_CMP) { xpt_free_path(wpath); isp_prt(isp, ISP_LOGERR, "%s: could not allocate path", __func__); return; } ccb = xpt_alloc_ccb(); ISP_LOCK(isp); status = cam_periph_alloc(isptargctor, NULL, isptargdtor, isptargstart, "isptarg", CAM_PERIPH_BIO, wpath, NULL, 0, softc); if (status != CAM_REQ_CMP) { ISP_UNLOCK(isp); isp_prt(isp, ISP_LOGERR, "%s: cam_periph_alloc for wildcard failed", __func__); goto out; } wperiph = cam_periph_find(wpath, "isptarg"); if (wperiph == NULL) { ISP_UNLOCK(isp); isp_prt(isp, ISP_LOGERR, "%s: wildcard periph already allocated but doesn't exist", __func__); goto out; } status = cam_periph_alloc(isptargctor, NULL, isptargdtor, isptargstart, "isptarg", CAM_PERIPH_BIO, path, NULL, 0, softc); if (status != CAM_REQ_CMP) { ISP_UNLOCK(isp); isp_prt(isp, ISP_LOGERR, "%s: cam_periph_alloc failed", __func__); goto out; } periph = cam_periph_find(path, "isptarg"); if (periph == NULL) { ISP_UNLOCK(isp); isp_prt(isp, ISP_LOGERR, "%s: periph already allocated but doesn't exist", __func__); goto out; } status = xpt_register_async(AC_CONTRACT, isptargasync, isp, wpath); if (status != CAM_REQ_CMP) { ISP_UNLOCK(isp); isp_prt(isp, ISP_LOGERR, "%s: xpt_register_async failed", __func__); goto out; } ISP_UNLOCK(isp); ccb = xpt_alloc_ccb(); /* * Make sure role is none. */ xpt_setup_ccb(&ccb->ccb_h, periph->path, 10); ccb->ccb_h.func_code = XPT_SET_SIM_KNOB; ccb->knob.xport_specific.fc.role = KNOB_ROLE_NONE; #ifdef ISP_TEST_WWNS ccb->knob.xport_specific.fc.valid = KNOB_VALID_ROLE | KNOB_VALID_ADDRESS; ccb->knob.xport_specific.fc.wwnn = 0x508004d000000000ULL | (device_get_unit(isp->isp_osinfo.dev) << 8) | (chan << 16); ccb->knob.xport_specific.fc.wwpn = 0x508004d000000001ULL | (device_get_unit(isp->isp_osinfo.dev) << 8) | (chan << 16); #else ccb->knob.xport_specific.fc.valid = KNOB_VALID_ROLE; #endif ISP_LOCK(isp); xpt_action(ccb); ISP_UNLOCK(isp); /* * Now enable luns */ xpt_setup_ccb(&ccb->ccb_h, periph->path, 10); ccb->ccb_h.func_code = XPT_EN_LUN; ccb->cel.enable = 1; ISP_LOCK(isp); xpt_action(ccb); ISP_UNLOCK(isp); if (ccb->ccb_h.status != CAM_REQ_CMP) { xpt_free_ccb(ccb); xpt_print(periph->path, "failed to enable lun (0x%x)\n", ccb->ccb_h.status); goto out; } xpt_setup_ccb(&ccb->ccb_h, wperiph->path, 10); ccb->ccb_h.func_code = XPT_EN_LUN; ccb->cel.enable = 1; ISP_LOCK(isp); xpt_action(ccb); ISP_UNLOCK(isp); if (ccb->ccb_h.status != CAM_REQ_CMP) { xpt_free_ccb(ccb); xpt_print(wperiph->path, "failed to enable lun (0x%x)\n", ccb->ccb_h.status); goto out; } xpt_free_ccb(ccb); /* * Add resources */ ISP_GET_PC_ADDR(isp, chan, target_proc, wchan); for (i = 0; i < 4; i++) { ccb = malloc(sizeof (*ccb), M_ISPTARG, M_WAITOK | M_ZERO); xpt_setup_ccb(&ccb->ccb_h, wperiph->path, 1); ccb->ccb_h.func_code = XPT_ACCEPT_TARGET_IO; ccb->ccb_h.cbfcnp = isptarg_done; ISP_LOCK(isp); xpt_action(ccb); ISP_UNLOCK(isp); } for (i = 0; i < NISP_TARG_CMDS; i++) { ccb = malloc(sizeof (*ccb), M_ISPTARG, M_WAITOK | M_ZERO); xpt_setup_ccb(&ccb->ccb_h, periph->path, 1); ccb->ccb_h.func_code = XPT_ACCEPT_TARGET_IO; ccb->ccb_h.cbfcnp = isptarg_done; ISP_LOCK(isp); xpt_action(ccb); ISP_UNLOCK(isp); } for (i = 0; i < 4; i++) { ccb = malloc(sizeof (*ccb), M_ISPTARG, M_WAITOK | M_ZERO); xpt_setup_ccb(&ccb->ccb_h, wperiph->path, 1); ccb->ccb_h.func_code = XPT_IMMEDIATE_NOTIFY; ccb->ccb_h.cbfcnp = isptarg_done; ISP_LOCK(isp); xpt_action(ccb); ISP_UNLOCK(isp); } for (i = 0; i < NISP_TARG_NOTIFIES; i++) { ccb = malloc(sizeof (*ccb), M_ISPTARG, M_WAITOK | M_ZERO); xpt_setup_ccb(&ccb->ccb_h, periph->path, 1); ccb->ccb_h.func_code = XPT_IMMEDIATE_NOTIFY; ccb->ccb_h.cbfcnp = isptarg_done; ISP_LOCK(isp); xpt_action(ccb); ISP_UNLOCK(isp); } /* * Now turn it all back on */ xpt_setup_ccb(&ccb->ccb_h, periph->path, 10); ccb->ccb_h.func_code = XPT_SET_SIM_KNOB; ccb->knob.xport_specific.fc.valid = KNOB_VALID_ROLE; ccb->knob.xport_specific.fc.role = KNOB_ROLE_TARGET; ISP_LOCK(isp); xpt_action(ccb); ISP_UNLOCK(isp); /* * Okay, while things are still active, sleep... */ ISP_LOCK(isp); for (;;) { ISP_GET_PC(isp, chan, proc_active, i); if (i == 0) { break; } msleep(wchan, &isp->isp_lock, PUSER, "tsnooze", 0); } ISP_UNLOCK(isp); out: if (wperiph) { cam_periph_invalidate(wperiph); } if (periph) { cam_periph_invalidate(periph); } if (junk_data) { free(junk_data, M_ISPTARG); } if (disk_data) { free(disk_data, M_ISPTARG); } if (softc) { free(softc, M_ISPTARG); } xpt_free_path(path); xpt_free_path(wpath); } static void isp_target_thread_pi(void *arg) { struct isp_spi *pi = arg; isp_target_thread(cam_sim_softc(pi->sim), cam_sim_bus(pi->sim)); } static void isp_target_thread_fc(void *arg) { struct isp_fc *fc = arg; isp_target_thread(cam_sim_softc(fc->sim), cam_sim_bus(fc->sim)); } static int isptarg_rwparm(uint8_t *cdb, uint8_t *dp, uint64_t dl, uint32_t offset, uint8_t **kp, uint32_t *tl, int *lp) { uint32_t cnt, curcnt; uint64_t lba; switch (cdb[0]) { case WRITE_16: case READ_16: cnt = (((uint32_t)cdb[10]) << 24) | (((uint32_t)cdb[11]) << 16) | (((uint32_t)cdb[12]) << 8) | ((uint32_t)cdb[13]); lba = (((uint64_t)cdb[2]) << 56) | (((uint64_t)cdb[3]) << 48) | (((uint64_t)cdb[4]) << 40) | (((uint64_t)cdb[5]) << 32) | (((uint64_t)cdb[6]) << 24) | (((uint64_t)cdb[7]) << 16) | (((uint64_t)cdb[8]) << 8) | ((uint64_t)cdb[9]); break; case WRITE_12: case READ_12: cnt = (((uint32_t)cdb[6]) << 16) | (((uint32_t)cdb[7]) << 8) | ((u_int32_t)cdb[8]); lba = (((uint32_t)cdb[2]) << 24) | (((uint32_t)cdb[3]) << 16) | (((uint32_t)cdb[4]) << 8) | ((uint32_t)cdb[5]); break; case WRITE_10: case READ_10: cnt = (((uint32_t)cdb[7]) << 8) | ((u_int32_t)cdb[8]); lba = (((uint32_t)cdb[2]) << 24) | (((uint32_t)cdb[3]) << 16) | (((uint32_t)cdb[4]) << 8) | ((uint32_t)cdb[5]); break; case WRITE_6: case READ_6: cnt = cdb[4]; if (cnt == 0) { cnt = 256; } lba = (((uint32_t)cdb[1] & 0x1f) << 16) | (((uint32_t)cdb[2]) << 8) | ((uint32_t)cdb[3]); break; default: return (-1); } cnt <<= DISK_SHIFT; lba <<= DISK_SHIFT; if (offset == cnt) { *lp = 1; return (0); } if (lba + cnt > dl) { return (-1); } curcnt = MAX_ISP_TARG_TRANSFER; if (offset + curcnt >= cnt) { curcnt = cnt - offset; *lp = 1; } else { *lp = 0; } *tl = curcnt; *kp = &dp[lba + offset]; return (0); } #endif #endif static void isp_cam_async(void *cbarg, uint32_t code, struct cam_path *path, void *arg) { struct cam_sim *sim; int bus, tgt; ispsoftc_t *isp; sim = (struct cam_sim *)cbarg; isp = (ispsoftc_t *) cam_sim_softc(sim); bus = cam_sim_bus(sim); tgt = xpt_path_target_id(path); switch (code) { case AC_LOST_DEVICE: if (IS_SCSI(isp)) { uint16_t oflags, nflags; sdparam *sdp = SDPARAM(isp, bus); if (tgt >= 0) { nflags = sdp->isp_devparam[tgt].nvrm_flags; #ifndef ISP_TARGET_MODE nflags &= DPARM_SAFE_DFLT; if (isp->isp_loaded_fw) { nflags |= DPARM_NARROW | DPARM_ASYNC; } #else nflags = DPARM_DEFAULT; #endif oflags = sdp->isp_devparam[tgt].goal_flags; sdp->isp_devparam[tgt].goal_flags = nflags; sdp->isp_devparam[tgt].dev_update = 1; sdp->update = 1; (void) isp_control(isp, ISPCTL_UPDATE_PARAMS, bus); sdp->isp_devparam[tgt].goal_flags = oflags; } } break; default: isp_prt(isp, ISP_LOGWARN, "isp_cam_async: Code 0x%x", code); break; } } static void isp_poll(struct cam_sim *sim) { ispsoftc_t *isp = cam_sim_softc(sim); uint32_t isr; uint16_t sema, mbox; if (ISP_READ_ISR(isp, &isr, &sema, &mbox)) { isp_intr(isp, isr, sema, mbox); } } static void isp_watchdog(void *arg) { struct ccb_scsiio *xs = arg; ispsoftc_t *isp; uint32_t ohandle = ISP_HANDLE_FREE, handle; isp = XS_ISP(xs); handle = isp_find_handle(isp, xs); if (handle != ISP_HANDLE_FREE && !XS_CMD_WPEND_P(xs)) { isp_xs_prt(isp, xs, ISP_LOGWARN, "first watchdog (handle 0x%x) timed out- deferring for grace period", handle); callout_reset(&PISP_PCMD(xs)->wdog, 2 * hz, isp_watchdog, xs); XS_CMD_S_WPEND(xs); return; } XS_C_TACTIVE(xs); /* * Hand crank the interrupt code just to be sure the command isn't stuck somewhere. */ if (handle != ISP_HANDLE_FREE) { uint32_t isr; uint16_t sema, mbox; if (ISP_READ_ISR(isp, &isr, &sema, &mbox) != 0) { isp_intr(isp, isr, sema, mbox); } ohandle = handle; handle = isp_find_handle(isp, xs); } if (handle != ISP_HANDLE_FREE) { /* * Try and make sure the command is really dead before * we release the handle (and DMA resources) for reuse. * * If we are successful in aborting the command then * we're done here because we'll get the command returned * back separately. */ if (isp_control(isp, ISPCTL_ABORT_CMD, xs) == 0) { return; } /* * Note that after calling the above, the command may in * fact have been completed. */ xs = isp_find_xs(isp, handle); /* * If the command no longer exists, then we won't * be able to find the xs again with this handle. */ if (xs == NULL) { return; } /* * After this point, the command is really dead. */ if (XS_XFRLEN(xs)) { ISP_DMAFREE(isp, xs, handle); } isp_destroy_handle(isp, handle); isp_prt(isp, ISP_LOGERR, "%s: timeout for handle 0x%x", __func__, handle); XS_SETERR(xs, CAM_CMD_TIMEOUT); isp_prt_endcmd(isp, xs); isp_done(xs); } else { if (ohandle != ISP_HANDLE_FREE) { isp_prt(isp, ISP_LOGWARN, "%s: timeout for handle 0x%x, recovered during interrupt", __func__, ohandle); } else { isp_prt(isp, ISP_LOGWARN, "%s: timeout for handle already free", __func__); } } } static void isp_make_here(ispsoftc_t *isp, int chan, int tgt) { union ccb *ccb; struct isp_fc *fc = ISP_FC_PC(isp, chan); if (isp_autoconfig == 0) { return; } /* * Allocate a CCB, create a wildcard path for this target and schedule a rescan. */ ccb = xpt_alloc_ccb_nowait(); if (ccb == NULL) { isp_prt(isp, ISP_LOGWARN, "Chan %d unable to alloc CCB for rescan", chan); return; } if (xpt_create_path(&ccb->ccb_h.path, xpt_periph, cam_sim_path(fc->sim), tgt, CAM_LUN_WILDCARD) != CAM_REQ_CMP) { isp_prt(isp, ISP_LOGWARN, "unable to create path for rescan"); xpt_free_ccb(ccb); return; } xpt_rescan(ccb); } static void isp_make_gone(ispsoftc_t *isp, int chan, int tgt) { struct cam_path *tp; struct isp_fc *fc = ISP_FC_PC(isp, chan); if (isp_autoconfig == 0) { return; } if (xpt_create_path(&tp, NULL, cam_sim_path(fc->sim), tgt, CAM_LUN_WILDCARD) == CAM_REQ_CMP) { xpt_async(AC_LOST_DEVICE, tp, NULL); xpt_free_path(tp); } } /* * Gone Device Timer Function- when we have decided that a device has gone * away, we wait a specific period of time prior to telling the OS it has * gone away. * * This timer function fires once a second and then scans the port database * for devices that are marked dead but still have a virtual target assigned. * We decrement a counter for that port database entry, and when it hits zero, * we tell the OS the device has gone away. */ static void isp_gdt(void *arg) { struct isp_fc *fc = arg; taskqueue_enqueue(taskqueue_thread, &fc->gtask); } static void isp_gdt_task(void *arg, int pending) { struct isp_fc *fc = arg; ispsoftc_t *isp = fc->isp; int chan = fc - isp->isp_osinfo.pc.fc; fcportdb_t *lp; int dbidx, tgt, more_to_do = 0; ISP_LOCK(isp); isp_prt(isp, ISP_LOGDEBUG0, "Chan %d GDT timer expired", chan); for (dbidx = 0; dbidx < MAX_FC_TARG; dbidx++) { lp = &FCPARAM(isp, chan)->portdb[dbidx]; if (lp->state != FC_PORTDB_STATE_ZOMBIE) { continue; } if (lp->dev_map_idx == 0 || lp->target_mode) { continue; } if (lp->gone_timer != 0) { isp_prt(isp, ISP_LOGSANCFG, "%s: Chan %d more to do for target %u (timer=%u)", __func__, chan, lp->dev_map_idx - 1, lp->gone_timer); lp->gone_timer -= 1; more_to_do++; continue; } tgt = lp->dev_map_idx - 1; FCPARAM(isp, chan)->isp_dev_map[tgt] = 0; lp->dev_map_idx = 0; lp->state = FC_PORTDB_STATE_NIL; isp_prt(isp, ISP_LOGCONFIG, prom3, chan, lp->portid, tgt, "Gone Device Timeout"); isp_make_gone(isp, chan, tgt); } if (fc->ready) { if (more_to_do) { callout_reset(&fc->gdt, hz, isp_gdt, fc); } else { callout_deactivate(&fc->gdt); isp_prt(isp, ISP_LOGSANCFG, "Chan %d Stopping Gone Device Timer @ %lu", chan, (unsigned long) time_uptime); } } ISP_UNLOCK(isp); } /* * Loop Down Timer Function- when loop goes down, a timer is started and * and after it expires we come here and take all probational devices that * the OS knows about and the tell the OS that they've gone away. * * We don't clear the devices out of our port database because, when loop * come back up, we have to do some actual cleanup with the chip at that * point (implicit PLOGO, e.g., to get the chip's port database state right). */ static void isp_ldt(void *arg) { struct isp_fc *fc = arg; taskqueue_enqueue(taskqueue_thread, &fc->ltask); } static void isp_ldt_task(void *arg, int pending) { struct isp_fc *fc = arg; ispsoftc_t *isp = fc->isp; int chan = fc - isp->isp_osinfo.pc.fc; fcportdb_t *lp; int dbidx, tgt, i; ISP_LOCK(isp); isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d Loop Down Timer expired @ %lu", chan, (unsigned long) time_uptime); callout_deactivate(&fc->ldt); /* * Notify to the OS all targets who we now consider have departed. */ for (dbidx = 0; dbidx < MAX_FC_TARG; dbidx++) { lp = &FCPARAM(isp, chan)->portdb[dbidx]; if (lp->state != FC_PORTDB_STATE_PROBATIONAL) { continue; } if (lp->dev_map_idx == 0 || lp->target_mode) { continue; } /* * XXX: CLEAN UP AND COMPLETE ANY PENDING COMMANDS FIRST! */ for (i = 0; i < isp->isp_maxcmds; i++) { struct ccb_scsiio *xs; if (!ISP_VALID_HANDLE(isp, isp->isp_xflist[i].handle)) { continue; } if ((xs = isp->isp_xflist[i].cmd) == NULL) { continue; } if (dbidx != (FCPARAM(isp, chan)->isp_dev_map[XS_TGT(xs)] - 1)) { continue; } isp_prt(isp, ISP_LOGWARN, "command handle 0x%08x for %d.%d.%d orphaned by loop down timeout", isp->isp_xflist[i].handle, chan, XS_TGT(xs), XS_LUN(xs)); } /* * Mark that we've announced that this device is gone.... */ lp->reserved = 1; /* * but *don't* change the state of the entry. Just clear * any target id stuff and announce to CAM that the * device is gone. This way any necessary PLOGO stuff * will happen when loop comes back up. */ tgt = lp->dev_map_idx - 1; FCPARAM(isp, chan)->isp_dev_map[tgt] = 0; lp->dev_map_idx = 0; lp->state = FC_PORTDB_STATE_NIL; isp_prt(isp, ISP_LOGCONFIG, prom3, chan, lp->portid, tgt, "Loop Down Timeout"); isp_make_gone(isp, chan, tgt); } if (FCPARAM(isp, chan)->role & ISP_ROLE_INITIATOR) { isp_unfreeze_loopdown(isp, chan); } /* * The loop down timer has expired. Wake up the kthread * to notice that fact (or make it false). */ fc->loop_dead = 1; fc->loop_down_time = fc->loop_down_limit+1; wakeup(fc); ISP_UNLOCK(isp); } static void isp_kthread(void *arg) { struct isp_fc *fc = arg; ispsoftc_t *isp = fc->isp; int chan = fc - isp->isp_osinfo.pc.fc; int slp = 0; mtx_lock(&isp->isp_osinfo.lock); for (;;) { int lb, lim; isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "%s: Chan %d checking FC state", __func__, chan); lb = isp_fc_runstate(isp, chan, 250000); /* * Our action is different based upon whether we're supporting * Initiator mode or not. If we are, we might freeze the simq * when loop is down and set all sorts of different delays to * check again. * * If not, we simply just wait for loop to come up. */ if (lb && (FCPARAM(isp, chan)->role & ISP_ROLE_INITIATOR)) { /* * Increment loop down time by the last sleep interval */ fc->loop_down_time += slp; if (lb < 0) { isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "%s: Chan %d FC loop not up (down count %d)", __func__, chan, fc->loop_down_time); } else { isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "%s: Chan %d FC got to %d (down count %d)", __func__, chan, lb, fc->loop_down_time); } /* * If we've never seen loop up and we've waited longer * than quickboot time, or we've seen loop up but we've * waited longer than loop_down_limit, give up and go * to sleep until loop comes up. */ if (FCPARAM(isp, chan)->loop_seen_once == 0) { lim = isp_quickboot_time; } else { lim = fc->loop_down_limit; } if (fc->loop_down_time >= lim) { isp_freeze_loopdown(isp, chan, "loop limit hit"); slp = 0; } else if (fc->loop_down_time < 10) { slp = 1; } else if (fc->loop_down_time < 30) { slp = 5; } else if (fc->loop_down_time < 60) { slp = 10; } else if (fc->loop_down_time < 120) { slp = 20; } else { slp = 30; } } else if (lb) { isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "%s: Chan %d FC Loop Down", __func__, chan); fc->loop_down_time += slp; slp = 60; } else { isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "%s: Chan %d FC state OK", __func__, chan); fc->loop_down_time = 0; slp = 0; } /* * If this is past the first loop up or the loop is dead and if we'd frozen the simq, unfreeze it * now so that CAM can start sending us commands. * * If the FC state isn't okay yet, they'll hit that in isp_start which will freeze the queue again * or kill the commands, as appropriate. */ if (FCPARAM(isp, chan)->loop_seen_once || fc->loop_dead) { isp_unfreeze_loopdown(isp, chan); } isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "%s: Chan %d sleep time %d", __func__, chan, slp); msleep(fc, &isp->isp_osinfo.lock, PRIBIO, "ispf", slp * hz); /* * If slp is zero, we're waking up for the first time after * things have been okay. In this case, we set a deferral state * for all commands and delay hysteresis seconds before starting * the FC state evaluation. This gives the loop/fabric a chance * to settle. */ if (slp == 0 && fc->hysteresis) { isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "%s: Chan %d sleep hysteresis ticks %d", __func__, chan, fc->hysteresis * hz); mtx_unlock(&isp->isp_osinfo.lock); pause("ispt", fc->hysteresis * hz); mtx_lock(&isp->isp_osinfo.lock); } } mtx_unlock(&isp->isp_osinfo.lock); } static void isp_action(struct cam_sim *sim, union ccb *ccb) { int bus, tgt, ts, error, lim; ispsoftc_t *isp; struct ccb_trans_settings *cts; CAM_DEBUG(ccb->ccb_h.path, CAM_DEBUG_TRACE, ("isp_action\n")); isp = (ispsoftc_t *)cam_sim_softc(sim); mtx_assert(&isp->isp_lock, MA_OWNED); if (isp->isp_state != ISP_RUNSTATE && ccb->ccb_h.func_code == XPT_SCSI_IO) { isp_init(isp); if (isp->isp_state != ISP_INITSTATE) { /* * Lie. Say it was a selection timeout. */ ccb->ccb_h.status = CAM_SEL_TIMEOUT | CAM_DEV_QFRZN; xpt_freeze_devq(ccb->ccb_h.path, 1); xpt_done(ccb); return; } isp->isp_state = ISP_RUNSTATE; } isp_prt(isp, ISP_LOGDEBUG2, "isp_action code %x", ccb->ccb_h.func_code); ISP_PCMD(ccb) = NULL; switch (ccb->ccb_h.func_code) { case XPT_SCSI_IO: /* Execute the requested I/O operation */ bus = XS_CHANNEL(ccb); /* * Do a couple of preliminary checks... */ if ((ccb->ccb_h.flags & CAM_CDB_POINTER) != 0) { if ((ccb->ccb_h.flags & CAM_CDB_PHYS) != 0) { ccb->ccb_h.status = CAM_REQ_INVALID; xpt_done(ccb); break; } } #ifdef DIAGNOSTIC if (ccb->ccb_h.target_id > (ISP_MAX_TARGETS(isp) - 1)) { xpt_print(ccb->ccb_h.path, "invalid target\n"); ccb->ccb_h.status = CAM_PATH_INVALID; } else if (ccb->ccb_h.target_lun > (ISP_MAX_LUNS(isp) - 1)) { xpt_print(ccb->ccb_h.path, "invalid lun\n"); ccb->ccb_h.status = CAM_PATH_INVALID; } if (ccb->ccb_h.status == CAM_PATH_INVALID) { xpt_done(ccb); break; } #endif ccb->csio.scsi_status = SCSI_STATUS_OK; if (isp_get_pcmd(isp, ccb)) { isp_prt(isp, ISP_LOGWARN, "out of PCMDs"); cam_freeze_devq(ccb->ccb_h.path); cam_release_devq(ccb->ccb_h.path, RELSIM_RELEASE_AFTER_TIMEOUT, 0, 250, 0); xpt_done(ccb); break; } error = isp_start((XS_T *) ccb); switch (error) { case CMD_QUEUED: XS_CMD_S_CLEAR(ccb); ccb->ccb_h.status |= CAM_SIM_QUEUED; if (ccb->ccb_h.timeout == CAM_TIME_INFINITY) { break; } ts = ccb->ccb_h.timeout; if (ts == CAM_TIME_DEFAULT) { ts = 60*1000; } ts = isp_mstohz(ts); XS_S_TACTIVE(ccb); callout_reset(&PISP_PCMD(ccb)->wdog, ts, isp_watchdog, ccb); break; case CMD_RQLATER: /* * We get this result for FC devices if the loop state isn't ready yet * or if the device in question has gone zombie on us. * * If we've never seen Loop UP at all, we requeue this request and wait * for the initial loop up delay to expire. */ lim = ISP_FC_PC(isp, bus)->loop_down_limit; if (FCPARAM(isp, bus)->loop_seen_once == 0 || ISP_FC_PC(isp, bus)->loop_down_time >= lim) { if (FCPARAM(isp, bus)->loop_seen_once == 0) { isp_prt(isp, ISP_LOGDEBUG0, "%d.%d loop not seen yet @ %lu", XS_TGT(ccb), XS_LUN(ccb), (unsigned long) time_uptime); } else { isp_prt(isp, ISP_LOGDEBUG0, "%d.%d downtime (%d) > lim (%d)", XS_TGT(ccb), XS_LUN(ccb), ISP_FC_PC(isp, bus)->loop_down_time, lim); } ccb->ccb_h.status = CAM_SEL_TIMEOUT|CAM_DEV_QFRZN; xpt_freeze_devq(ccb->ccb_h.path, 1); isp_free_pcmd(isp, ccb); xpt_done(ccb); break; } isp_prt(isp, ISP_LOGDEBUG0, "%d.%d retry later", XS_TGT(ccb), XS_LUN(ccb)); cam_freeze_devq(ccb->ccb_h.path); cam_release_devq(ccb->ccb_h.path, RELSIM_RELEASE_AFTER_TIMEOUT, 0, 1000, 0); XS_SETERR(ccb, CAM_REQUEUE_REQ); isp_free_pcmd(isp, ccb); xpt_done(ccb); break; case CMD_EAGAIN: isp_free_pcmd(isp, ccb); cam_freeze_devq(ccb->ccb_h.path); cam_release_devq(ccb->ccb_h.path, RELSIM_RELEASE_AFTER_TIMEOUT, 0, 100, 0); XS_SETERR(ccb, CAM_REQUEUE_REQ); xpt_done(ccb); break; case CMD_COMPLETE: isp_done((struct ccb_scsiio *) ccb); break; default: isp_prt(isp, ISP_LOGERR, "What's this? 0x%x at %d in file %s", error, __LINE__, __FILE__); XS_SETERR(ccb, CAM_REQ_CMP_ERR); isp_free_pcmd(isp, ccb); xpt_done(ccb); } break; #ifdef ISP_TARGET_MODE case XPT_EN_LUN: /* Enable/Disable LUN as a target */ if (ccb->cel.enable) { isp_enable_lun(isp, ccb); } else { isp_disable_lun(isp, ccb); } break; case XPT_IMMED_NOTIFY: case XPT_IMMEDIATE_NOTIFY: /* Add Immediate Notify Resource */ case XPT_ACCEPT_TARGET_IO: /* Add Accept Target IO Resource */ { tstate_t *tptr = get_lun_statep(isp, XS_CHANNEL(ccb), ccb->ccb_h.target_lun); if (tptr == NULL) { tptr = get_lun_statep(isp, XS_CHANNEL(ccb), CAM_LUN_WILDCARD); } if (tptr == NULL) { const char *str; uint32_t tag; if (ccb->ccb_h.func_code == XPT_IMMEDIATE_NOTIFY) { str = "XPT_IMMEDIATE_NOTIFY"; tag = ccb->cin1.seq_id; } else { tag = ccb->atio.tag_id; str = "XPT_ACCEPT_TARGET_IO"; } ISP_PATH_PRT(isp, ISP_LOGWARN, ccb->ccb_h.path, "%s: [0x%x] no state pointer found for %s\n", __func__, tag, str); dump_tstates(isp, XS_CHANNEL(ccb)); ccb->ccb_h.status = CAM_DEV_NOT_THERE; break; } ccb->ccb_h.sim_priv.entries[0].field = 0; ccb->ccb_h.sim_priv.entries[1].ptr = isp; ccb->ccb_h.flags = 0; if (ccb->ccb_h.func_code == XPT_ACCEPT_TARGET_IO) { if (ccb->atio.tag_id) { atio_private_data_t *atp = isp_get_atpd(isp, tptr, ccb->atio.tag_id); if (atp) { isp_put_atpd(isp, tptr, atp); } } tptr->atio_count++; SLIST_INSERT_HEAD(&tptr->atios, &ccb->ccb_h, sim_links.sle); ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, ccb->ccb_h.path, "Put FREE ATIO (tag id 0x%x), count now %d\n", - ((struct ccb_accept_tio *)ccb)->tag_id, tptr->atio_count); + ccb->atio.tag_id, tptr->atio_count); } else if (ccb->ccb_h.func_code == XPT_IMMEDIATE_NOTIFY) { if (ccb->cin1.tag_id) { inot_private_data_t *ntp = isp_find_ntpd(isp, tptr, ccb->cin1.tag_id, ccb->cin1.seq_id); if (ntp) { isp_put_ntpd(isp, tptr, ntp); } } tptr->inot_count++; SLIST_INSERT_HEAD(&tptr->inots, &ccb->ccb_h, sim_links.sle); ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, ccb->ccb_h.path, "Put FREE INOT, (seq id 0x%x) count now %d\n", - ((struct ccb_immediate_notify *)ccb)->seq_id, tptr->inot_count); + ccb->cin1.seq_id, tptr->inot_count); } else if (ccb->ccb_h.func_code == XPT_IMMED_NOTIFY) { tptr->inot_count++; SLIST_INSERT_HEAD(&tptr->inots, &ccb->ccb_h, sim_links.sle); ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, ccb->ccb_h.path, "Put FREE INOT, (seq id 0x%x) count now %d\n", - ((struct ccb_immediate_notify *)ccb)->seq_id, tptr->inot_count); + ccb->cin1.seq_id, tptr->inot_count); } rls_lun_statep(isp, tptr); ccb->ccb_h.status = CAM_REQ_INPROG; break; } case XPT_NOTIFY_ACK: ccb->ccb_h.status = CAM_REQ_CMP_ERR; break; case XPT_NOTIFY_ACKNOWLEDGE: /* notify ack */ { tstate_t *tptr; inot_private_data_t *ntp; /* * XXX: Because we cannot guarantee that the path information in the notify acknowledge ccb * XXX: matches that for the immediate notify, we have to *search* for the notify structure */ /* * All the relevant path information is in the associated immediate notify */ ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, ccb->ccb_h.path, "%s: [0x%x] NOTIFY ACKNOWLEDGE for 0x%x seen\n", __func__, ccb->cna2.tag_id, ccb->cna2.seq_id); ntp = get_ntp_from_tagdata(isp, ccb->cna2.tag_id, ccb->cna2.seq_id, &tptr); if (ntp == NULL) { ISP_PATH_PRT(isp, ISP_LOGWARN, ccb->ccb_h.path, "%s: [0x%x] XPT_NOTIFY_ACKNOWLEDGE of 0x%x cannot find ntp private data\n", __func__, ccb->cna2.tag_id, ccb->cna2.seq_id); ccb->ccb_h.status = CAM_DEV_NOT_THERE; xpt_done(ccb); break; } if (isp_handle_platform_target_notify_ack(isp, &ntp->rd.nt)) { rls_lun_statep(isp, tptr); cam_freeze_devq(ccb->ccb_h.path); cam_release_devq(ccb->ccb_h.path, RELSIM_RELEASE_AFTER_TIMEOUT, 0, 1000, 0); XS_SETERR(ccb, CAM_REQUEUE_REQ); break; } isp_put_ntpd(isp, tptr, ntp); rls_lun_statep(isp, tptr); ccb->ccb_h.status = CAM_REQ_CMP; ISP_PATH_PRT(isp, ISP_LOGTDEBUG0, ccb->ccb_h.path, "%s: [0x%x] calling xpt_done for tag 0x%x\n", __func__, ccb->cna2.tag_id, ccb->cna2.seq_id); xpt_done(ccb); break; } case XPT_CONT_TARGET_IO: isp_target_start_ctio(isp, ccb); break; #endif case XPT_RESET_DEV: /* BDR the specified SCSI device */ bus = cam_sim_bus(xpt_path_sim(ccb->ccb_h.path)); tgt = ccb->ccb_h.target_id; tgt |= (bus << 16); error = isp_control(isp, ISPCTL_RESET_DEV, bus, tgt); if (error) { ccb->ccb_h.status = CAM_REQ_CMP_ERR; } else { ccb->ccb_h.status = CAM_REQ_CMP; } xpt_done(ccb); break; case XPT_ABORT: /* Abort the specified CCB */ { union ccb *accb = ccb->cab.abort_ccb; switch (accb->ccb_h.func_code) { #ifdef ISP_TARGET_MODE case XPT_ACCEPT_TARGET_IO: isp_target_mark_aborted(isp, ccb); break; #endif case XPT_SCSI_IO: error = isp_control(isp, ISPCTL_ABORT_CMD, ccb); if (error) { ccb->ccb_h.status = CAM_UA_ABORT; } else { ccb->ccb_h.status = CAM_REQ_CMP; } break; default: ccb->ccb_h.status = CAM_REQ_INVALID; break; } /* * This is not a queued CCB, so the caller expects it to be * complete when control is returned. */ break; } #define IS_CURRENT_SETTINGS(c) (c->type == CTS_TYPE_CURRENT_SETTINGS) case XPT_SET_TRAN_SETTINGS: /* Nexus Settings */ cts = &ccb->cts; if (!IS_CURRENT_SETTINGS(cts)) { ccb->ccb_h.status = CAM_REQ_INVALID; xpt_done(ccb); break; } tgt = cts->ccb_h.target_id; bus = cam_sim_bus(xpt_path_sim(cts->ccb_h.path)); if (IS_SCSI(isp)) { struct ccb_trans_settings_scsi *scsi = &cts->proto_specific.scsi; struct ccb_trans_settings_spi *spi = &cts->xport_specific.spi; sdparam *sdp = SDPARAM(isp, bus); uint16_t *dptr; if (spi->valid == 0 && scsi->valid == 0) { ccb->ccb_h.status = CAM_REQ_CMP; xpt_done(ccb); break; } /* * We always update (internally) from goal_flags * so any request to change settings just gets * vectored to that location. */ dptr = &sdp->isp_devparam[tgt].goal_flags; if ((spi->valid & CTS_SPI_VALID_DISC) != 0) { if ((spi->flags & CTS_SPI_FLAGS_DISC_ENB) != 0) *dptr |= DPARM_DISC; else *dptr &= ~DPARM_DISC; } if ((scsi->valid & CTS_SCSI_VALID_TQ) != 0) { if ((scsi->flags & CTS_SCSI_FLAGS_TAG_ENB) != 0) *dptr |= DPARM_TQING; else *dptr &= ~DPARM_TQING; } if ((spi->valid & CTS_SPI_VALID_BUS_WIDTH) != 0) { if (spi->bus_width == MSG_EXT_WDTR_BUS_16_BIT) *dptr |= DPARM_WIDE; else *dptr &= ~DPARM_WIDE; } /* * XXX: FIX ME */ if ((spi->valid & CTS_SPI_VALID_SYNC_OFFSET) && (spi->valid & CTS_SPI_VALID_SYNC_RATE) && (spi->sync_period && spi->sync_offset)) { *dptr |= DPARM_SYNC; /* * XXX: CHECK FOR LEGALITY */ sdp->isp_devparam[tgt].goal_period = spi->sync_period; sdp->isp_devparam[tgt].goal_offset = spi->sync_offset; } else { *dptr &= ~DPARM_SYNC; } isp_prt(isp, ISP_LOGDEBUG0, "SET (%d.%d.%d) to flags %x off %x per %x", bus, tgt, cts->ccb_h.target_lun, sdp->isp_devparam[tgt].goal_flags, sdp->isp_devparam[tgt].goal_offset, sdp->isp_devparam[tgt].goal_period); sdp->isp_devparam[tgt].dev_update = 1; sdp->update = 1; } ccb->ccb_h.status = CAM_REQ_CMP; xpt_done(ccb); break; case XPT_GET_TRAN_SETTINGS: cts = &ccb->cts; tgt = cts->ccb_h.target_id; bus = cam_sim_bus(xpt_path_sim(cts->ccb_h.path)); if (IS_FC(isp)) { fcparam *fcp = FCPARAM(isp, bus); struct ccb_trans_settings_scsi *scsi = &cts->proto_specific.scsi; struct ccb_trans_settings_fc *fc = &cts->xport_specific.fc; unsigned int hdlidx; cts->protocol = PROTO_SCSI; cts->protocol_version = SCSI_REV_2; cts->transport = XPORT_FC; cts->transport_version = 0; scsi->valid = CTS_SCSI_VALID_TQ; scsi->flags = CTS_SCSI_FLAGS_TAG_ENB; fc->valid = CTS_FC_VALID_SPEED; fc->bitrate = 100000; fc->bitrate *= fcp->isp_gbspeed; hdlidx = fcp->isp_dev_map[tgt] - 1; if (hdlidx < MAX_FC_TARG) { fcportdb_t *lp = &fcp->portdb[hdlidx]; fc->wwnn = lp->node_wwn; fc->wwpn = lp->port_wwn; fc->port = lp->portid; fc->valid |= CTS_FC_VALID_WWNN | CTS_FC_VALID_WWPN | CTS_FC_VALID_PORT; } } else { struct ccb_trans_settings_scsi *scsi = &cts->proto_specific.scsi; struct ccb_trans_settings_spi *spi = &cts->xport_specific.spi; sdparam *sdp = SDPARAM(isp, bus); uint16_t dval, pval, oval; if (IS_CURRENT_SETTINGS(cts)) { sdp->isp_devparam[tgt].dev_refresh = 1; sdp->update = 1; (void) isp_control(isp, ISPCTL_UPDATE_PARAMS, bus); dval = sdp->isp_devparam[tgt].actv_flags; oval = sdp->isp_devparam[tgt].actv_offset; pval = sdp->isp_devparam[tgt].actv_period; } else { dval = sdp->isp_devparam[tgt].nvrm_flags; oval = sdp->isp_devparam[tgt].nvrm_offset; pval = sdp->isp_devparam[tgt].nvrm_period; } cts->protocol = PROTO_SCSI; cts->protocol_version = SCSI_REV_2; cts->transport = XPORT_SPI; cts->transport_version = 2; spi->valid = 0; scsi->valid = 0; spi->flags = 0; scsi->flags = 0; if (dval & DPARM_DISC) { spi->flags |= CTS_SPI_FLAGS_DISC_ENB; } if ((dval & DPARM_SYNC) && oval && pval) { spi->sync_offset = oval; spi->sync_period = pval; } else { spi->sync_offset = 0; spi->sync_period = 0; } spi->valid |= CTS_SPI_VALID_SYNC_OFFSET; spi->valid |= CTS_SPI_VALID_SYNC_RATE; spi->valid |= CTS_SPI_VALID_BUS_WIDTH; if (dval & DPARM_WIDE) { spi->bus_width = MSG_EXT_WDTR_BUS_16_BIT; } else { spi->bus_width = MSG_EXT_WDTR_BUS_8_BIT; } if (cts->ccb_h.target_lun != CAM_LUN_WILDCARD) { scsi->valid = CTS_SCSI_VALID_TQ; if (dval & DPARM_TQING) { scsi->flags |= CTS_SCSI_FLAGS_TAG_ENB; } spi->valid |= CTS_SPI_VALID_DISC; } isp_prt(isp, ISP_LOGDEBUG0, "GET %s (%d.%d.%d) to flags %x off %x per %x", IS_CURRENT_SETTINGS(cts)? "ACTIVE" : "NVRAM", bus, tgt, cts->ccb_h.target_lun, dval, oval, pval); } ccb->ccb_h.status = CAM_REQ_CMP; xpt_done(ccb); break; case XPT_CALC_GEOMETRY: cam_calc_geometry(&ccb->ccg, 1); xpt_done(ccb); break; case XPT_RESET_BUS: /* Reset the specified bus */ bus = cam_sim_bus(sim); error = isp_control(isp, ISPCTL_RESET_BUS, bus); if (error) { ccb->ccb_h.status = CAM_REQ_CMP_ERR; xpt_done(ccb); break; } if (bootverbose) { xpt_print(ccb->ccb_h.path, "reset bus on channel %d\n", bus); } if (IS_FC(isp)) { xpt_async(AC_BUS_RESET, ISP_FC_PC(isp, bus)->path, 0); } else { xpt_async(AC_BUS_RESET, ISP_SPI_PC(isp, bus)->path, 0); } ccb->ccb_h.status = CAM_REQ_CMP; xpt_done(ccb); break; case XPT_TERM_IO: /* Terminate the I/O process */ ccb->ccb_h.status = CAM_REQ_INVALID; xpt_done(ccb); break; case XPT_SET_SIM_KNOB: /* Set SIM knobs */ { struct ccb_sim_knob *kp = &ccb->knob; fcparam *fcp; - if (!IS_FC(isp)) { ccb->ccb_h.status = CAM_REQ_INVALID; xpt_done(ccb); break; } bus = cam_sim_bus(xpt_path_sim(kp->ccb_h.path)); fcp = FCPARAM(isp, bus); if (kp->xport_specific.fc.valid & KNOB_VALID_ADDRESS) { fcp->isp_wwnn = ISP_FC_PC(isp, bus)->def_wwnn = kp->xport_specific.fc.wwnn; fcp->isp_wwpn = ISP_FC_PC(isp, bus)->def_wwpn = kp->xport_specific.fc.wwpn; isp_prt(isp, ISP_LOGALL, "Setting Channel %d wwns to 0x%jx 0x%jx", bus, fcp->isp_wwnn, fcp->isp_wwpn); } ccb->ccb_h.status = CAM_REQ_CMP; if (kp->xport_specific.fc.valid & KNOB_VALID_ROLE) { int rchange = 0; int newrole = 0; switch (kp->xport_specific.fc.role) { case KNOB_ROLE_NONE: if (fcp->role != ISP_ROLE_NONE) { rchange = 1; newrole = ISP_ROLE_NONE; } break; case KNOB_ROLE_TARGET: if (fcp->role != ISP_ROLE_TARGET) { rchange = 1; newrole = ISP_ROLE_TARGET; } break; case KNOB_ROLE_INITIATOR: if (fcp->role != ISP_ROLE_INITIATOR) { rchange = 1; newrole = ISP_ROLE_INITIATOR; } break; case KNOB_ROLE_BOTH: #if 0 if (fcp->role != ISP_ROLE_BOTH) { rchange = 1; newrole = ISP_ROLE_BOTH; } #else /* * We don't really support dual role at present on FC cards. * * We should, but a bunch of things are currently broken, * so don't allow it. */ isp_prt(isp, ISP_LOGERR, "cannot support dual role at present"); ccb->ccb_h.status = CAM_REQ_INVALID; #endif break; } if (rchange) { + ISP_PATH_PRT(isp, ISP_LOGCONFIG, ccb->ccb_h.path, "changing role on from %d to %d\n", fcp->role, newrole); if (isp_fc_change_role(isp, bus, newrole) != 0) { ccb->ccb_h.status = CAM_REQ_CMP_ERR; #ifdef ISP_TARGET_MODE } else if (newrole == ISP_ROLE_TARGET || newrole == ISP_ROLE_BOTH) { - isp_enable_deferred_luns(isp, bus); + ccb->ccb_h.status = isp_enable_deferred_luns(isp, bus); #endif } } } xpt_done(ccb); break; } - case XPT_GET_SIM_KNOB: /* Set SIM knobs */ + case XPT_GET_SIM_KNOB: /* Get SIM knobs */ { struct ccb_sim_knob *kp = &ccb->knob; if (IS_FC(isp)) { fcparam *fcp; bus = cam_sim_bus(xpt_path_sim(kp->ccb_h.path)); fcp = FCPARAM(isp, bus); kp->xport_specific.fc.wwnn = fcp->isp_wwnn; kp->xport_specific.fc.wwpn = fcp->isp_wwpn; switch (fcp->role) { case ISP_ROLE_NONE: kp->xport_specific.fc.role = KNOB_ROLE_NONE; break; case ISP_ROLE_TARGET: kp->xport_specific.fc.role = KNOB_ROLE_TARGET; break; case ISP_ROLE_INITIATOR: kp->xport_specific.fc.role = KNOB_ROLE_INITIATOR; break; case ISP_ROLE_BOTH: kp->xport_specific.fc.role = KNOB_ROLE_BOTH; break; } kp->xport_specific.fc.valid = KNOB_VALID_ADDRESS | KNOB_VALID_ROLE; ccb->ccb_h.status = CAM_REQ_CMP; } else { ccb->ccb_h.status = CAM_REQ_INVALID; } xpt_done(ccb); break; } case XPT_PATH_INQ: /* Path routing inquiry */ { struct ccb_pathinq *cpi = &ccb->cpi; cpi->version_num = 1; #ifdef ISP_TARGET_MODE cpi->target_sprt = PIT_PROCESSOR | PIT_DISCONNECT | PIT_TERM_IO; #else cpi->target_sprt = 0; #endif cpi->hba_eng_cnt = 0; cpi->max_target = ISP_MAX_TARGETS(isp) - 1; cpi->max_lun = ISP_MAX_LUNS(isp) - 1; cpi->bus_id = cam_sim_bus(sim); bus = cam_sim_bus(xpt_path_sim(cpi->ccb_h.path)); if (IS_FC(isp)) { fcparam *fcp = FCPARAM(isp, bus); cpi->hba_misc = PIM_NOBUSRESET; /* * Because our loop ID can shift from time to time, * make our initiator ID out of range of our bus. */ cpi->initiator_id = cpi->max_target + 1; /* * Set base transfer capabilities for Fibre Channel, for this HBA. */ if (IS_25XX(isp)) { cpi->base_transfer_speed = 8000000; } else if (IS_24XX(isp)) { cpi->base_transfer_speed = 4000000; } else if (IS_23XX(isp)) { cpi->base_transfer_speed = 2000000; } else { cpi->base_transfer_speed = 1000000; } cpi->hba_inquiry = PI_TAG_ABLE; cpi->transport = XPORT_FC; cpi->transport_version = 0; cpi->xport_specific.fc.wwnn = fcp->isp_wwnn; cpi->xport_specific.fc.wwpn = fcp->isp_wwpn; cpi->xport_specific.fc.port = fcp->isp_portid; cpi->xport_specific.fc.bitrate = fcp->isp_gbspeed * 1000; } else { sdparam *sdp = SDPARAM(isp, bus); cpi->hba_inquiry = PI_SDTR_ABLE|PI_TAG_ABLE|PI_WIDE_16; cpi->hba_misc = 0; cpi->initiator_id = sdp->isp_initiator_id; cpi->base_transfer_speed = 3300; cpi->transport = XPORT_SPI; cpi->transport_version = 2; } cpi->protocol = PROTO_SCSI; cpi->protocol_version = SCSI_REV_2; strncpy(cpi->sim_vid, "FreeBSD", SIM_IDLEN); strncpy(cpi->hba_vid, "Qlogic", HBA_IDLEN); strncpy(cpi->dev_name, cam_sim_name(sim), DEV_IDLEN); cpi->unit_number = cam_sim_unit(sim); cpi->ccb_h.status = CAM_REQ_CMP; xpt_done(ccb); break; } default: ccb->ccb_h.status = CAM_REQ_INVALID; xpt_done(ccb); break; } } #define ISPDDB (CAM_DEBUG_INFO|CAM_DEBUG_TRACE|CAM_DEBUG_CDB) void isp_done(XS_T *sccb) { ispsoftc_t *isp = XS_ISP(sccb); uint32_t status; if (XS_NOERR(sccb)) XS_SETERR(sccb, CAM_REQ_CMP); if ((sccb->ccb_h.status & CAM_STATUS_MASK) == CAM_REQ_CMP && (sccb->scsi_status != SCSI_STATUS_OK)) { sccb->ccb_h.status &= ~CAM_STATUS_MASK; if ((sccb->scsi_status == SCSI_STATUS_CHECK_COND) && (sccb->ccb_h.status & CAM_AUTOSNS_VALID) == 0) { sccb->ccb_h.status |= CAM_AUTOSENSE_FAIL; } else { sccb->ccb_h.status |= CAM_SCSI_STATUS_ERROR; } } sccb->ccb_h.status &= ~CAM_SIM_QUEUED; status = sccb->ccb_h.status & CAM_STATUS_MASK; if (status != CAM_REQ_CMP) { if (status != CAM_SEL_TIMEOUT) isp_prt(isp, ISP_LOGDEBUG0, "target %d lun %d CAM status 0x%x SCSI status 0x%x", XS_TGT(sccb), XS_LUN(sccb), sccb->ccb_h.status, sccb->scsi_status); if ((sccb->ccb_h.status & CAM_DEV_QFRZN) == 0) { sccb->ccb_h.status |= CAM_DEV_QFRZN; xpt_freeze_devq(sccb->ccb_h.path, 1); } } if ((CAM_DEBUGGED(sccb->ccb_h.path, ISPDDB)) && (sccb->ccb_h.status & CAM_STATUS_MASK) != CAM_REQ_CMP) { xpt_print(sccb->ccb_h.path, "cam completion status 0x%x\n", sccb->ccb_h.status); } XS_CMD_S_DONE(sccb); if (XS_TACTIVE_P(sccb)) callout_stop(&PISP_PCMD(sccb)->wdog); XS_CMD_S_CLEAR(sccb); isp_free_pcmd(isp, (union ccb *) sccb); xpt_done((union ccb *) sccb); } void isp_async(ispsoftc_t *isp, ispasync_t cmd, ...) { int bus; static const char prom[] = "Chan %d PortID 0x%06x handle 0x%x role %s %s WWPN 0x%08x%08x"; static const char prom2[] = "Chan %d PortID 0x%06x handle 0x%x role %s %s tgt %u WWPN 0x%08x%08x"; char *msg = NULL; target_id_t tgt; fcportdb_t *lp; struct isp_fc *fc; struct cam_path *tmppath; va_list ap; switch (cmd) { case ISPASYNC_NEW_TGT_PARAMS: { struct ccb_trans_settings_scsi *scsi; struct ccb_trans_settings_spi *spi; int flags, tgt; sdparam *sdp; struct ccb_trans_settings cts; memset(&cts, 0, sizeof (struct ccb_trans_settings)); va_start(ap, cmd); bus = va_arg(ap, int); tgt = va_arg(ap, int); va_end(ap); sdp = SDPARAM(isp, bus); if (xpt_create_path(&tmppath, NULL, cam_sim_path(ISP_SPI_PC(isp, bus)->sim), tgt, CAM_LUN_WILDCARD) != CAM_REQ_CMP) { isp_prt(isp, ISP_LOGWARN, "isp_async cannot make temp path for %d.%d", tgt, bus); break; } flags = sdp->isp_devparam[tgt].actv_flags; cts.type = CTS_TYPE_CURRENT_SETTINGS; cts.protocol = PROTO_SCSI; cts.transport = XPORT_SPI; scsi = &cts.proto_specific.scsi; spi = &cts.xport_specific.spi; if (flags & DPARM_TQING) { scsi->valid |= CTS_SCSI_VALID_TQ; scsi->flags |= CTS_SCSI_FLAGS_TAG_ENB; } if (flags & DPARM_DISC) { spi->valid |= CTS_SPI_VALID_DISC; spi->flags |= CTS_SPI_FLAGS_DISC_ENB; } spi->flags |= CTS_SPI_VALID_BUS_WIDTH; if (flags & DPARM_WIDE) { spi->bus_width = MSG_EXT_WDTR_BUS_16_BIT; } else { spi->bus_width = MSG_EXT_WDTR_BUS_8_BIT; } if (flags & DPARM_SYNC) { spi->valid |= CTS_SPI_VALID_SYNC_RATE; spi->valid |= CTS_SPI_VALID_SYNC_OFFSET; spi->sync_period = sdp->isp_devparam[tgt].actv_period; spi->sync_offset = sdp->isp_devparam[tgt].actv_offset; } isp_prt(isp, ISP_LOGDEBUG2, "NEW_TGT_PARAMS bus %d tgt %d period %x offset %x flags %x", bus, tgt, sdp->isp_devparam[tgt].actv_period, sdp->isp_devparam[tgt].actv_offset, flags); xpt_setup_ccb(&cts.ccb_h, tmppath, 1); xpt_async(AC_TRANSFER_NEG, tmppath, &cts); xpt_free_path(tmppath); break; } case ISPASYNC_BUS_RESET: { va_start(ap, cmd); bus = va_arg(ap, int); va_end(ap); isp_prt(isp, ISP_LOGINFO, "SCSI bus reset on bus %d detected", bus); if (IS_FC(isp)) { xpt_async(AC_BUS_RESET, ISP_FC_PC(isp, bus)->path, NULL); } else { xpt_async(AC_BUS_RESET, ISP_SPI_PC(isp, bus)->path, NULL); } break; } case ISPASYNC_LIP: if (msg == NULL) { msg = "LIP Received"; } /* FALLTHROUGH */ case ISPASYNC_LOOP_RESET: if (msg == NULL) { msg = "LOOP Reset"; } /* FALLTHROUGH */ case ISPASYNC_LOOP_DOWN: { if (msg == NULL) { msg = "LOOP Down"; } va_start(ap, cmd); bus = va_arg(ap, int); va_end(ap); FCPARAM(isp, bus)->link_active = 0; fc = ISP_FC_PC(isp, bus); if (cmd == ISPASYNC_LOOP_DOWN && fc->ready) { /* * We don't do any simq freezing if we are only in target mode */ if (FCPARAM(isp, bus)->role & ISP_ROLE_INITIATOR) { if (fc->path) { isp_freeze_loopdown(isp, bus, msg); } if (!callout_active(&fc->ldt)) { callout_reset(&fc->ldt, fc->loop_down_limit * hz, isp_ldt, fc); isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Starting Loop Down Timer @ %lu", (unsigned long) time_uptime); } } } isp_prt(isp, ISP_LOGINFO, "Chan %d: %s", bus, msg); break; } case ISPASYNC_LOOP_UP: va_start(ap, cmd); bus = va_arg(ap, int); va_end(ap); fc = ISP_FC_PC(isp, bus); /* * Now we just note that Loop has come up. We don't * actually do anything because we're waiting for a * Change Notify before activating the FC cleanup * thread to look at the state of the loop again. */ FCPARAM(isp, bus)->link_active = 1; fc->loop_dead = 0; fc->loop_down_time = 0; isp_prt(isp, ISP_LOGINFO, "Chan %d Loop UP", bus); break; case ISPASYNC_DEV_ARRIVED: va_start(ap, cmd); bus = va_arg(ap, int); lp = va_arg(ap, fcportdb_t *); va_end(ap); fc = ISP_FC_PC(isp, bus); lp->reserved = 0; lp->gone_timer = 0; if ((FCPARAM(isp, bus)->role & ISP_ROLE_INITIATOR) && (lp->roles & (SVC3_TGT_ROLE >> SVC3_ROLE_SHIFT))) { int dbidx = lp - FCPARAM(isp, bus)->portdb; int i; for (i = 0; i < MAX_FC_TARG; i++) { if (i >= FL_ID && i <= SNS_ID) { continue; } if (FCPARAM(isp, bus)->isp_dev_map[i] == 0) { break; } } if (i < MAX_FC_TARG) { FCPARAM(isp, bus)->isp_dev_map[i] = dbidx + 1; lp->dev_map_idx = i + 1; } else { isp_prt(isp, ISP_LOGWARN, "out of target ids"); isp_dump_portdb(isp, bus); } } if (lp->dev_map_idx) { tgt = lp->dev_map_idx - 1; isp_prt(isp, ISP_LOGCONFIG, prom2, bus, lp->portid, lp->handle, roles[lp->roles], "arrived at", tgt, (uint32_t) (lp->port_wwn >> 32), (uint32_t) lp->port_wwn); isp_make_here(isp, bus, tgt); } else { isp_prt(isp, ISP_LOGCONFIG, prom, bus, lp->portid, lp->handle, roles[lp->roles], "arrived", (uint32_t) (lp->port_wwn >> 32), (uint32_t) lp->port_wwn); } break; case ISPASYNC_DEV_CHANGED: va_start(ap, cmd); bus = va_arg(ap, int); lp = va_arg(ap, fcportdb_t *); va_end(ap); fc = ISP_FC_PC(isp, bus); lp->reserved = 0; lp->gone_timer = 0; if (isp_change_is_bad) { lp->state = FC_PORTDB_STATE_NIL; if (lp->dev_map_idx) { tgt = lp->dev_map_idx - 1; FCPARAM(isp, bus)->isp_dev_map[tgt] = 0; lp->dev_map_idx = 0; isp_prt(isp, ISP_LOGCONFIG, prom3, bus, lp->portid, tgt, "change is bad"); isp_make_gone(isp, bus, tgt); } else { isp_prt(isp, ISP_LOGCONFIG, prom, bus, lp->portid, lp->handle, roles[lp->roles], "changed and departed", (uint32_t) (lp->port_wwn >> 32), (uint32_t) lp->port_wwn); } } else { lp->portid = lp->new_portid; lp->roles = lp->new_roles; if (lp->dev_map_idx) { int t = lp->dev_map_idx - 1; FCPARAM(isp, bus)->isp_dev_map[t] = (lp - FCPARAM(isp, bus)->portdb) + 1; tgt = lp->dev_map_idx - 1; isp_prt(isp, ISP_LOGCONFIG, prom2, bus, lp->portid, lp->handle, roles[lp->roles], "changed at", tgt, (uint32_t) (lp->port_wwn >> 32), (uint32_t) lp->port_wwn); } else { isp_prt(isp, ISP_LOGCONFIG, prom, bus, lp->portid, lp->handle, roles[lp->roles], "changed", (uint32_t) (lp->port_wwn >> 32), (uint32_t) lp->port_wwn); } } break; case ISPASYNC_DEV_STAYED: va_start(ap, cmd); bus = va_arg(ap, int); lp = va_arg(ap, fcportdb_t *); va_end(ap); if (lp->dev_map_idx) { tgt = lp->dev_map_idx - 1; isp_prt(isp, ISP_LOGCONFIG, prom2, bus, lp->portid, lp->handle, roles[lp->roles], "stayed at", tgt, (uint32_t) (lp->port_wwn >> 32), (uint32_t) lp->port_wwn); } else { isp_prt(isp, ISP_LOGCONFIG, prom, bus, lp->portid, lp->handle, roles[lp->roles], "stayed", (uint32_t) (lp->port_wwn >> 32), (uint32_t) lp->port_wwn); } break; case ISPASYNC_DEV_GONE: va_start(ap, cmd); bus = va_arg(ap, int); lp = va_arg(ap, fcportdb_t *); va_end(ap); fc = ISP_FC_PC(isp, bus); /* * If this has a virtual target and we haven't marked it * that we're going to have isp_gdt tell the OS it's gone, * set the isp_gdt timer running on it. * * If it isn't marked that isp_gdt is going to get rid of it, * announce that it's gone. * */ if (lp->dev_map_idx && lp->reserved == 0) { lp->reserved = 1; lp->state = FC_PORTDB_STATE_ZOMBIE; lp->gone_timer = ISP_FC_PC(isp, bus)->gone_device_time; if (fc->ready && !callout_active(&fc->gdt)) { isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Chan %d Starting Gone Device Timer with %u seconds time now %lu", bus, lp->gone_timer, (unsigned long)time_uptime); callout_reset(&fc->gdt, hz, isp_gdt, fc); } tgt = lp->dev_map_idx - 1; isp_prt(isp, ISP_LOGCONFIG, prom2, bus, lp->portid, lp->handle, roles[lp->roles], "gone zombie at", tgt, (uint32_t) (lp->port_wwn >> 32), (uint32_t) lp->port_wwn); } else if (lp->reserved == 0) { isp_prt(isp, ISP_LOGCONFIG, prom, bus, lp->portid, lp->handle, roles[lp->roles], "departed", (uint32_t) (lp->port_wwn >> 32), (uint32_t) lp->port_wwn); } break; case ISPASYNC_CHANGE_NOTIFY: { char *msg; int evt, nphdl, nlstate, reason; va_start(ap, cmd); bus = va_arg(ap, int); evt = va_arg(ap, int); if (IS_24XX(isp) && evt == ISPASYNC_CHANGE_PDB) { nphdl = va_arg(ap, int); nlstate = va_arg(ap, int); reason = va_arg(ap, int); } else { nphdl = NIL_HANDLE; nlstate = reason = 0; } va_end(ap); fc = ISP_FC_PC(isp, bus); if (evt == ISPASYNC_CHANGE_PDB) { msg = "Chan %d Port Database Changed"; } else if (evt == ISPASYNC_CHANGE_SNS) { msg = "Chan %d Name Server Database Changed"; } else { msg = "Chan %d Other Change Notify"; } /* * If the loop down timer is running, cancel it. */ if (fc->ready && callout_active(&fc->ldt)) { isp_prt(isp, ISP_LOGSANCFG|ISP_LOGDEBUG0, "Stopping Loop Down Timer @ %lu", (unsigned long) time_uptime); callout_stop(&fc->ldt); } isp_prt(isp, ISP_LOGINFO, msg, bus); if (FCPARAM(isp, bus)->role & ISP_ROLE_INITIATOR) { isp_freeze_loopdown(isp, bus, msg); } wakeup(fc); break; } #ifdef ISP_TARGET_MODE case ISPASYNC_TARGET_NOTIFY: { isp_notify_t *notify; va_start(ap, cmd); notify = va_arg(ap, isp_notify_t *); va_end(ap); switch (notify->nt_ncode) { case NT_ABORT_TASK: case NT_ABORT_TASK_SET: case NT_CLEAR_ACA: case NT_CLEAR_TASK_SET: case NT_LUN_RESET: case NT_TARGET_RESET: /* * These are task management functions. */ isp_handle_platform_target_tmf(isp, notify); break; case NT_BUS_RESET: case NT_LIP_RESET: case NT_LINK_UP: case NT_LINK_DOWN: /* * No action need be taken here. */ break; case NT_HBA_RESET: isp_del_all_wwn_entries(isp, ISP_NOCHAN); break; case NT_LOGOUT: /* * This is device arrival/departure notification */ isp_handle_platform_target_notify_ack(isp, notify); break; case NT_ARRIVED: { struct ac_contract ac; struct ac_device_changed *fc; ac.contract_number = AC_CONTRACT_DEV_CHG; fc = (struct ac_device_changed *) ac.contract_data; fc->wwpn = notify->nt_wwn; fc->port = notify->nt_sid; fc->target = notify->nt_nphdl; fc->arrived = 1; xpt_async(AC_CONTRACT, ISP_FC_PC(isp, notify->nt_channel)->path, &ac); break; } case NT_DEPARTED: { struct ac_contract ac; struct ac_device_changed *fc; ac.contract_number = AC_CONTRACT_DEV_CHG; fc = (struct ac_device_changed *) ac.contract_data; fc->wwpn = notify->nt_wwn; fc->port = notify->nt_sid; fc->target = notify->nt_nphdl; fc->arrived = 0; xpt_async(AC_CONTRACT, ISP_FC_PC(isp, notify->nt_channel)->path, &ac); break; } default: isp_prt(isp, ISP_LOGALL, "target notify code 0x%x", notify->nt_ncode); isp_handle_platform_target_notify_ack(isp, notify); break; } break; } case ISPASYNC_TARGET_ACTION: { isphdr_t *hp; va_start(ap, cmd); hp = va_arg(ap, isphdr_t *); va_end(ap); switch (hp->rqs_entry_type) { default: isp_prt(isp, ISP_LOGWARN, "%s: unhandled target action 0x%x", __func__, hp->rqs_entry_type); break; case RQSTYPE_NOTIFY: if (IS_SCSI(isp)) { isp_handle_platform_notify_scsi(isp, (in_entry_t *) hp); } else if (IS_24XX(isp)) { isp_handle_platform_notify_24xx(isp, (in_fcentry_24xx_t *) hp); } else { isp_handle_platform_notify_fc(isp, (in_fcentry_t *) hp); } break; case RQSTYPE_ATIO: if (IS_24XX(isp)) { isp_handle_platform_atio7(isp, (at7_entry_t *) hp); } else { isp_handle_platform_atio(isp, (at_entry_t *) hp); } break; case RQSTYPE_ATIO2: isp_handle_platform_atio2(isp, (at2_entry_t *) hp); break; case RQSTYPE_CTIO7: case RQSTYPE_CTIO3: case RQSTYPE_CTIO2: case RQSTYPE_CTIO: isp_handle_platform_ctio(isp, hp); break; case RQSTYPE_ABTS_RCVD: { abts_t *abts = (abts_t *)hp; isp_notify_t notify, *nt = ¬ify; tstate_t *tptr; fcportdb_t *lp; uint16_t chan; uint32_t sid, did; did = (abts->abts_did_hi << 16) | abts->abts_did_lo; sid = (abts->abts_sid_hi << 16) | abts->abts_sid_lo; ISP_MEMZERO(nt, sizeof (isp_notify_t)); nt->nt_hba = isp; nt->nt_did = did; nt->nt_nphdl = abts->abts_nphdl; nt->nt_sid = sid; isp_find_chan_by_did(isp, did, &chan); if (chan == ISP_NOCHAN) { nt->nt_tgt = TGT_ANY; } else { nt->nt_tgt = FCPARAM(isp, chan)->isp_wwpn; if (isp_find_pdb_by_loopid(isp, chan, abts->abts_nphdl, &lp)) { nt->nt_wwn = lp->port_wwn; } else { nt->nt_wwn = INI_ANY; } } /* * Try hard to find the lun for this command. */ tptr = get_lun_statep_from_tag(isp, chan, abts->abts_rxid_task); if (tptr) { nt->nt_lun = xpt_path_lun_id(tptr->owner); rls_lun_statep(isp, tptr); } else { nt->nt_lun = LUN_ANY; } nt->nt_need_ack = 1; nt->nt_tagval = abts->abts_rxid_task; nt->nt_tagval |= (((uint64_t) abts->abts_rxid_abts) << 32); if (abts->abts_rxid_task == ISP24XX_NO_TASK) { isp_prt(isp, ISP_LOGTINFO, "[0x%x] ABTS from N-Port handle 0x%x Port 0x%06x has no task id (rx_id 0x%04x ox_id 0x%04x)", abts->abts_rxid_abts, abts->abts_nphdl, sid, abts->abts_rx_id, abts->abts_ox_id); } else { isp_prt(isp, ISP_LOGTINFO, "[0x%x] ABTS from N-Port handle 0x%x Port 0x%06x for task 0x%x (rx_id 0x%04x ox_id 0x%04x)", abts->abts_rxid_abts, abts->abts_nphdl, sid, abts->abts_rxid_task, abts->abts_rx_id, abts->abts_ox_id); } nt->nt_channel = chan; nt->nt_ncode = NT_ABORT_TASK; nt->nt_lreserved = hp; isp_handle_platform_target_tmf(isp, nt); break; } case RQSTYPE_ENABLE_LUN: case RQSTYPE_MODIFY_LUN: isp_ledone(isp, (lun_entry_t *) hp); break; } break; } #endif case ISPASYNC_FW_CRASH: { uint16_t mbox1, mbox6; mbox1 = ISP_READ(isp, OUTMAILBOX1); if (IS_DUALBUS(isp)) { mbox6 = ISP_READ(isp, OUTMAILBOX6); } else { mbox6 = 0; } isp_prt(isp, ISP_LOGERR, "Internal Firmware Error on bus %d @ RISC Address 0x%x", mbox6, mbox1); mbox1 = isp->isp_osinfo.mbox_sleep_ok; isp->isp_osinfo.mbox_sleep_ok = 0; isp_reinit(isp, 1); isp->isp_osinfo.mbox_sleep_ok = mbox1; isp_async(isp, ISPASYNC_FW_RESTARTED, NULL); break; } default: isp_prt(isp, ISP_LOGERR, "unknown isp_async event %d", cmd); break; } } /* * Locks are held before coming here. */ void isp_uninit(ispsoftc_t *isp) { if (IS_24XX(isp)) { ISP_WRITE(isp, BIU2400_HCCR, HCCR_2400_CMD_RESET); } else { ISP_WRITE(isp, HCCR, HCCR_CMD_RESET); } ISP_DISABLE_INTS(isp); } /* * When we want to get the 'default' WWNs (when lacking NVRAM), we pick them * up from our platform default (defww{p|n}n) and morph them based upon * channel. * * When we want to get the 'active' WWNs, we get NVRAM WWNs and then morph them * based upon channel. */ uint64_t isp_default_wwn(ispsoftc_t * isp, int chan, int isactive, int iswwnn) { uint64_t seed; struct isp_fc *fc = ISP_FC_PC(isp, chan); /* * If we're asking for a active WWN, the default overrides get * returned, otherwise the NVRAM value is picked. * * If we're asking for a default WWN, we just pick the default override. */ if (isactive) { seed = iswwnn ? fc->def_wwnn : fc->def_wwpn; if (seed) { return (seed); } seed = iswwnn ? FCPARAM(isp, chan)->isp_wwnn_nvram : FCPARAM(isp, chan)->isp_wwpn_nvram; if (seed) { return (seed); } return (0x400000007F000009ull); } else { seed = iswwnn ? fc->def_wwnn : fc->def_wwpn; } /* * For channel zero just return what we have. For either ACTIVE or * DEFAULT cases, we depend on default override of NVRAM values for * channel zero. */ if (chan == 0) { return (seed); } /* * For other channels, we are doing one of three things: * * 1. If what we have now is non-zero, return it. Otherwise we morph * values from channel 0. 2. If we're here for a WWPN we synthesize * it if Channel 0's wwpn has a type 2 NAA. 3. If we're here for a * WWNN we synthesize it if Channel 0's wwnn has a type 2 NAA. */ if (seed) { return (seed); } if (isactive) { seed = iswwnn ? FCPARAM(isp, 0)->isp_wwnn_nvram : FCPARAM(isp, 0)->isp_wwpn_nvram; } else { seed = iswwnn ? ISP_FC_PC(isp, 0)->def_wwnn : ISP_FC_PC(isp, 0)->def_wwpn; } if (((seed >> 60) & 0xf) == 2) { /* * The type 2 NAA fields for QLogic cards appear be laid out * thusly: * * bits 63..60 NAA == 2 bits 59..57 unused/zero bit 56 * port (1) or node (0) WWN distinguishor bit 48 * physical port on dual-port chips (23XX/24XX) * * This is somewhat nutty, particularly since bit 48 is * irrelevant as they assign separate serial numbers to * different physical ports anyway. * * We'll stick our channel number plus one first into bits * 57..59 and thence into bits 52..55 which allows for 8 bits * of channel which is comfortably more than our maximum * (126) now. */ seed &= ~0x0FF0000000000000ULL; if (iswwnn == 0) { seed |= ((uint64_t) (chan + 1) & 0xf) << 56; seed |= ((uint64_t) ((chan + 1) >> 4) & 0xf) << 52; } } else { seed = 0; } return (seed); } void isp_prt(ispsoftc_t *isp, int level, const char *fmt, ...) { int loc; char lbuf[128]; va_list ap; if (level != ISP_LOGALL && (level & isp->isp_dblev) == 0) { return; } sprintf(lbuf, "%s: ", device_get_nameunit(isp->isp_dev)); loc = strlen(lbuf); va_start(ap, fmt); vsnprintf(&lbuf[loc], sizeof (lbuf) - loc - 1, fmt, ap); va_end(ap); printf("%s\n", lbuf); } void isp_xs_prt(ispsoftc_t *isp, XS_T *xs, int level, const char *fmt, ...) { va_list ap; if (level != ISP_LOGALL && (level & isp->isp_dblev) == 0) { return; } xpt_print_path(xs->ccb_h.path); va_start(ap, fmt); vprintf(fmt, ap); va_end(ap); printf("\n"); } uint64_t isp_nanotime_sub(struct timespec *b, struct timespec *a) { uint64_t elapsed; struct timespec x = *b; timespecsub(&x, a); elapsed = GET_NANOSEC(&x); if (elapsed == 0) elapsed++; return (elapsed); } int isp_mbox_acquire(ispsoftc_t *isp) { if (isp->isp_osinfo.mboxbsy) { return (1); } else { isp->isp_osinfo.mboxcmd_done = 0; isp->isp_osinfo.mboxbsy = 1; return (0); } } void isp_mbox_wait_complete(ispsoftc_t *isp, mbreg_t *mbp) { unsigned int usecs = mbp->timeout; unsigned int max, olim, ilim; if (usecs == 0) { usecs = MBCMD_DEFAULT_TIMEOUT; } max = isp->isp_mbxwrk0 + 1; if (isp->isp_osinfo.mbox_sleep_ok) { unsigned int ms = (usecs + 999) / 1000; isp->isp_osinfo.mbox_sleep_ok = 0; isp->isp_osinfo.mbox_sleeping = 1; for (olim = 0; olim < max; olim++) { msleep(&isp->isp_mbxworkp, &isp->isp_osinfo.lock, PRIBIO, "ispmbx_sleep", isp_mstohz(ms)); if (isp->isp_osinfo.mboxcmd_done) { break; } } isp->isp_osinfo.mbox_sleep_ok = 1; isp->isp_osinfo.mbox_sleeping = 0; } else { for (olim = 0; olim < max; olim++) { for (ilim = 0; ilim < usecs; ilim += 100) { uint32_t isr; uint16_t sema, mbox; if (isp->isp_osinfo.mboxcmd_done) { break; } if (ISP_READ_ISR(isp, &isr, &sema, &mbox)) { isp_intr(isp, isr, sema, mbox); if (isp->isp_osinfo.mboxcmd_done) { break; } } ISP_DELAY(100); } if (isp->isp_osinfo.mboxcmd_done) { break; } } } if (isp->isp_osinfo.mboxcmd_done == 0) { isp_prt(isp, ISP_LOGWARN, "%s Mailbox Command (0x%x) Timeout (%uus) (started @ %s:%d)", isp->isp_osinfo.mbox_sleep_ok? "Interrupting" : "Polled", isp->isp_lastmbxcmd, usecs, mbp->func, mbp->lineno); mbp->param[0] = MBOX_TIMEOUT; isp->isp_osinfo.mboxcmd_done = 1; } } void isp_mbox_notify_done(ispsoftc_t *isp) { if (isp->isp_osinfo.mbox_sleeping) { wakeup(&isp->isp_mbxworkp); } isp->isp_osinfo.mboxcmd_done = 1; } void isp_mbox_release(ispsoftc_t *isp) { isp->isp_osinfo.mboxbsy = 0; } int isp_fc_scratch_acquire(ispsoftc_t *isp, int chan) { int ret = 0; if (isp->isp_osinfo.pc.fc[chan].fcbsy) { ret = -1; } else { isp->isp_osinfo.pc.fc[chan].fcbsy = 1; } return (ret); } int isp_mstohz(int ms) { int hz; struct timeval t; t.tv_sec = ms / 1000; t.tv_usec = (ms % 1000) * 1000; hz = tvtohz(&t); if (hz < 0) { hz = 0x7fffffff; } if (hz == 0) { hz = 1; } return (hz); } void isp_platform_intr(void *arg) { ispsoftc_t *isp = arg; uint32_t isr; uint16_t sema, mbox; ISP_LOCK(isp); isp->isp_intcnt++; if (ISP_READ_ISR(isp, &isr, &sema, &mbox) == 0) { isp->isp_intbogus++; } else { isp_intr(isp, isr, sema, mbox); } ISP_UNLOCK(isp); } void isp_common_dmateardown(ispsoftc_t *isp, struct ccb_scsiio *csio, uint32_t hdl) { if ((csio->ccb_h.flags & CAM_DIR_MASK) == CAM_DIR_IN) { bus_dmamap_sync(isp->isp_osinfo.dmat, PISP_PCMD(csio)->dmap, BUS_DMASYNC_POSTREAD); } else { bus_dmamap_sync(isp->isp_osinfo.dmat, PISP_PCMD(csio)->dmap, BUS_DMASYNC_POSTWRITE); } bus_dmamap_unload(isp->isp_osinfo.dmat, PISP_PCMD(csio)->dmap); } void isp_timer(void *arg) { ispsoftc_t *isp = arg; #ifdef ISP_TARGET_MODE isp_tmcmd_restart(isp); #endif callout_reset(&isp->isp_osinfo.tmo, hz, isp_timer, isp); } Index: stable/9/sys/dev/isp/isp_freebsd.h =================================================================== --- stable/9/sys/dev/isp/isp_freebsd.h (revision 237207) +++ stable/9/sys/dev/isp/isp_freebsd.h (revision 237208) @@ -1,681 +1,683 @@ /* $FreeBSD$ */ /*- * Qlogic ISP SCSI Host Adapter FreeBSD Wrapper Definitions * * Copyright (c) 1997-2008 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. * 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 _ISP_FREEBSD_H #define _ISP_FREEBSD_H #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "opt_ddb.h" #include "opt_isp.h" #define ISP_PLATFORM_VERSION_MAJOR 7 #define ISP_PLATFORM_VERSION_MINOR 0 /* * Efficiency- get rid of SBus code && tests unless we need them. */ #ifdef __sparc64__ #define ISP_SBUS_SUPPORTED 1 #else #define ISP_SBUS_SUPPORTED 0 #endif #define ISP_IFLAGS INTR_TYPE_CAM | INTR_ENTROPY | INTR_MPSAFE #ifdef ISP_TARGET_MODE #define ISP_TARGET_FUNCTIONS 1 #define ATPDPSIZE 4096 #include typedef struct { void * next; uint32_t orig_datalen; uint32_t bytes_xfered; uint32_t last_xframt; uint32_t tag; uint32_t lun; uint32_t nphdl; uint32_t sid; uint32_t portid; uint32_t oxid : 16, cdb0 : 8, : 1, dead : 1, tattr : 3, state : 3; } atio_private_data_t; #define ATPD_STATE_FREE 0 #define ATPD_STATE_ATIO 1 #define ATPD_STATE_CAM 2 #define ATPD_STATE_CTIO 3 #define ATPD_STATE_LAST_CTIO 4 #define ATPD_STATE_PDON 5 typedef union inot_private_data inot_private_data_t; union inot_private_data { inot_private_data_t *next; struct { isp_notify_t nt; /* must be first! */ uint8_t data[64]; /* sb QENTRY_LEN, but order of definitions is wrong */ uint32_t tag_id, seq_id; } rd; }; typedef struct tstate { SLIST_ENTRY(tstate) next; struct cam_path *owner; struct ccb_hdr_slist atios; struct ccb_hdr_slist inots; uint32_t hold; - int atio_count; - int inot_count; + uint32_t + enabled : 1, + atio_count : 15, + inot_count : 15; inot_private_data_t * restart_queue; inot_private_data_t * ntfree; inot_private_data_t ntpool[ATPDPSIZE]; atio_private_data_t * atfree; atio_private_data_t atpool[ATPDPSIZE]; } tstate_t; #define LUN_HASH_SIZE 32 #define LUN_HASH_FUNC(lun) ((lun) & (LUN_HASH_SIZE - 1)) #endif /* * Per command info. */ struct isp_pcmd { struct isp_pcmd * next; bus_dmamap_t dmap; /* dma map for this command */ struct ispsoftc * isp; /* containing isp */ struct callout wdog; /* watchdog timer */ }; #define ISP_PCMD(ccb) (ccb)->ccb_h.spriv_ptr1 #define PISP_PCMD(ccb) ((struct isp_pcmd *)ISP_PCMD(ccb)) /* * Per channel information */ SLIST_HEAD(tslist, tstate); struct isp_fc { struct cam_sim *sim; struct cam_path *path; struct ispsoftc *isp; struct proc *kproc; bus_dma_tag_t tdmat; bus_dmamap_t tdmap; uint64_t def_wwpn; uint64_t def_wwnn; uint32_t loop_down_time; uint32_t loop_down_limit; uint32_t gone_device_time; uint32_t #ifdef ISP_TARGET_MODE #ifdef ISP_INTERNAL_TARGET proc_active : 1, #endif tm_luns_enabled : 1, tm_enable_defer : 1, tm_enabled : 1, #endif simqfrozen : 3, default_id : 8, hysteresis : 8, def_role : 2, /* default role */ gdt_running : 1, loop_dead : 1, fcbsy : 1, ready : 1; struct callout ldt; /* loop down timer */ struct callout gdt; /* gone device timer */ struct task ltask; struct task gtask; #ifdef ISP_TARGET_MODE struct tslist lun_hash[LUN_HASH_SIZE]; #ifdef ISP_INTERNAL_TARGET struct proc * target_proc; #endif #endif }; struct isp_spi { struct cam_sim *sim; struct cam_path *path; uint32_t #ifdef ISP_TARGET_MODE #ifdef ISP_INTERNAL_TARGET proc_active : 1, #endif tm_luns_enabled : 1, tm_enable_defer : 1, tm_enabled : 1, #endif simqfrozen : 3, def_role : 2, iid : 4; #ifdef ISP_TARGET_MODE struct tslist lun_hash[LUN_HASH_SIZE]; #ifdef ISP_INTERNAL_TARGET struct proc * target_proc; #endif #endif }; struct isposinfo { /* * Linkage, locking, and identity */ struct mtx lock; device_t dev; struct cdev * cdev; struct intr_config_hook ehook; struct cam_devq * devq; /* * Firmware pointer */ const struct firmware * fw; /* * DMA related sdtuff */ bus_space_tag_t bus_tag; bus_dma_tag_t dmat; bus_space_handle_t bus_handle; bus_dma_tag_t cdmat; bus_dmamap_t cdmap; /* * Command and transaction related related stuff */ struct isp_pcmd * pcmd_pool; struct isp_pcmd * pcmd_free; uint32_t #ifdef ISP_TARGET_MODE tmwanted : 1, tmbusy : 1, #else : 2, #endif forcemulti : 1, timer_active : 1, autoconf : 1, ehook_active : 1, disabled : 1, mbox_sleeping : 1, mbox_sleep_ok : 1, mboxcmd_done : 1, mboxbsy : 1; struct callout tmo; /* general timer */ /* * misc- needs to be sorted better XXXXXX */ int framesize; int exec_throttle; int cont_max; #ifdef ISP_TARGET_MODE cam_status * rptr; #endif /* * Per-type private storage... */ union { struct isp_fc *fc; struct isp_spi *spi; void *ptr; } pc; }; #define ISP_FC_PC(isp, chan) (&(isp)->isp_osinfo.pc.fc[(chan)]) #define ISP_SPI_PC(isp, chan) (&(isp)->isp_osinfo.pc.spi[(chan)]) #define ISP_GET_PC(isp, chan, tag, rslt) \ if (IS_SCSI(isp)) { \ rslt = ISP_SPI_PC(isp, chan)-> tag; \ } else { \ rslt = ISP_FC_PC(isp, chan)-> tag; \ } #define ISP_GET_PC_ADDR(isp, chan, tag, rp) \ if (IS_SCSI(isp)) { \ rp = &ISP_SPI_PC(isp, chan)-> tag; \ } else { \ rp = &ISP_FC_PC(isp, chan)-> tag; \ } #define ISP_SET_PC(isp, chan, tag, val) \ if (IS_SCSI(isp)) { \ ISP_SPI_PC(isp, chan)-> tag = val; \ } else { \ ISP_FC_PC(isp, chan)-> tag = val; \ } #define isp_lock isp_osinfo.lock #define isp_bus_tag isp_osinfo.bus_tag #define isp_bus_handle isp_osinfo.bus_handle /* * Locking macros... */ #define ISP_LOCK(isp) mtx_lock(&isp->isp_osinfo.lock) #define ISP_UNLOCK(isp) mtx_unlock(&isp->isp_osinfo.lock) /* * Required Macros/Defines */ #define ISP_FC_SCRLEN 0x1000 #define ISP_MEMZERO(a, b) memset(a, 0, b) #define ISP_MEMCPY memcpy #define ISP_SNPRINTF snprintf #define ISP_DELAY DELAY #define ISP_SLEEP(isp, x) DELAY(x) #define ISP_MIN imin #ifndef DIAGNOSTIC #define ISP_INLINE __inline #else #define ISP_INLINE #endif #define NANOTIME_T struct timespec #define GET_NANOTIME nanotime #define GET_NANOSEC(x) ((x)->tv_sec * 1000000000 + (x)->tv_nsec) #define NANOTIME_SUB isp_nanotime_sub #define MAXISPREQUEST(isp) ((IS_FC(isp) || IS_ULTRA2(isp))? 1024 : 256) #define MEMORYBARRIER(isp, type, offset, size, chan) \ switch (type) { \ case SYNC_SFORDEV: \ { \ struct isp_fc *fc = ISP_FC_PC(isp, chan); \ bus_dmamap_sync(fc->tdmat, fc->tdmap, \ BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE); \ break; \ } \ case SYNC_REQUEST: \ bus_dmamap_sync(isp->isp_osinfo.cdmat, \ isp->isp_osinfo.cdmap, \ BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE); \ break; \ case SYNC_SFORCPU: \ { \ struct isp_fc *fc = ISP_FC_PC(isp, chan); \ bus_dmamap_sync(fc->tdmat, fc->tdmap, \ BUS_DMASYNC_POSTREAD | BUS_DMASYNC_POSTWRITE); \ break; \ } \ case SYNC_RESULT: \ bus_dmamap_sync(isp->isp_osinfo.cdmat, \ isp->isp_osinfo.cdmap, \ BUS_DMASYNC_POSTREAD | BUS_DMASYNC_POSTWRITE); \ break; \ case SYNC_REG: \ bus_space_barrier(isp->isp_osinfo.bus_tag, \ isp->isp_osinfo.bus_handle, offset, size, \ BUS_SPACE_BARRIER_READ | BUS_SPACE_BARRIER_WRITE); \ break; \ default: \ break; \ } #define MBOX_ACQUIRE isp_mbox_acquire #define MBOX_WAIT_COMPLETE isp_mbox_wait_complete #define MBOX_NOTIFY_COMPLETE isp_mbox_notify_done #define MBOX_RELEASE isp_mbox_release #define FC_SCRATCH_ACQUIRE isp_fc_scratch_acquire #define FC_SCRATCH_RELEASE(isp, chan) isp->isp_osinfo.pc.fc[chan].fcbsy = 0 #ifndef SCSI_GOOD #define SCSI_GOOD SCSI_STATUS_OK #endif #ifndef SCSI_CHECK #define SCSI_CHECK SCSI_STATUS_CHECK_COND #endif #ifndef SCSI_BUSY #define SCSI_BUSY SCSI_STATUS_BUSY #endif #ifndef SCSI_QFULL #define SCSI_QFULL SCSI_STATUS_QUEUE_FULL #endif #define XS_T struct ccb_scsiio #define XS_DMA_ADDR_T bus_addr_t #define XS_GET_DMA64_SEG(a, b, c) \ { \ ispds64_t *d = a; \ bus_dma_segment_t *e = b; \ uint32_t f = c; \ e += f; \ d->ds_base = DMA_LO32(e->ds_addr); \ d->ds_basehi = DMA_HI32(e->ds_addr); \ d->ds_count = e->ds_len; \ } #define XS_GET_DMA_SEG(a, b, c) \ { \ ispds_t *d = a; \ bus_dma_segment_t *e = b; \ uint32_t f = c; \ e += f; \ d->ds_base = DMA_LO32(e->ds_addr); \ d->ds_count = e->ds_len; \ } #define XS_ISP(ccb) cam_sim_softc(xpt_path_sim((ccb)->ccb_h.path)) #define XS_CHANNEL(ccb) cam_sim_bus(xpt_path_sim((ccb)->ccb_h.path)) #define XS_TGT(ccb) (ccb)->ccb_h.target_id #define XS_LUN(ccb) (ccb)->ccb_h.target_lun #define XS_CDBP(ccb) \ (((ccb)->ccb_h.flags & CAM_CDB_POINTER)? \ (ccb)->cdb_io.cdb_ptr : (ccb)->cdb_io.cdb_bytes) #define XS_CDBLEN(ccb) (ccb)->cdb_len #define XS_XFRLEN(ccb) (ccb)->dxfer_len #define XS_TIME(ccb) (ccb)->ccb_h.timeout #define XS_GET_RESID(ccb) (ccb)->resid #define XS_SET_RESID(ccb, r) (ccb)->resid = r #define XS_STSP(ccb) (&(ccb)->scsi_status) #define XS_SNSP(ccb) (&(ccb)->sense_data) #define XS_SNSLEN(ccb) \ imin((sizeof((ccb)->sense_data)), ccb->sense_len - ccb->sense_resid) #define XS_SNSKEY(ccb) (scsi_get_sense_key(&(ccb)->sense_data, \ ccb->sense_len - ccb->sense_resid, \ /*show_errors*/ 1)) #define XS_SNSASC(ccb) (scsi_get_asc(&(ccb)->sense_data, \ ccb->sense_len - ccb->sense_resid, \ /*show_errors*/ 1)) #define XS_SNSASCQ(ccb) (scsi_get_ascq(&(ccb)->sense_data, \ ccb->sense_len - ccb->sense_resid, \ /*show_errors*/ 1)) #define XS_TAG_P(ccb) \ (((ccb)->ccb_h.flags & CAM_TAG_ACTION_VALID) && \ (ccb)->tag_action != CAM_TAG_ACTION_NONE) #define XS_TAG_TYPE(ccb) \ ((ccb->tag_action == MSG_SIMPLE_Q_TAG)? REQFLAG_STAG : \ ((ccb->tag_action == MSG_HEAD_OF_Q_TAG)? REQFLAG_HTAG : REQFLAG_OTAG)) #define XS_SETERR(ccb, v) (ccb)->ccb_h.status &= ~CAM_STATUS_MASK, \ (ccb)->ccb_h.status |= v, \ (ccb)->ccb_h.spriv_field0 |= ISP_SPRIV_ERRSET # define HBA_NOERROR CAM_REQ_INPROG # define HBA_BOTCH CAM_UNREC_HBA_ERROR # define HBA_CMDTIMEOUT CAM_CMD_TIMEOUT # define HBA_SELTIMEOUT CAM_SEL_TIMEOUT # define HBA_TGTBSY CAM_SCSI_STATUS_ERROR # define HBA_BUSRESET CAM_SCSI_BUS_RESET # define HBA_ABORTED CAM_REQ_ABORTED # define HBA_DATAOVR CAM_DATA_RUN_ERR # define HBA_ARQFAIL CAM_AUTOSENSE_FAIL #define XS_ERR(ccb) ((ccb)->ccb_h.status & CAM_STATUS_MASK) #define XS_NOERR(ccb) \ (((ccb)->ccb_h.spriv_field0 & ISP_SPRIV_ERRSET) == 0 || \ ((ccb)->ccb_h.status & CAM_STATUS_MASK) == CAM_REQ_INPROG) #define XS_INITERR(ccb) \ XS_SETERR(ccb, CAM_REQ_INPROG), (ccb)->ccb_h.spriv_field0 = 0 #define XS_SAVE_SENSE(xs, sense_ptr, slen) do { \ (xs)->ccb_h.status |= CAM_AUTOSNS_VALID; \ memset(&(xs)->sense_data, 0, sizeof((xs)->sense_data)); \ memcpy(&(xs)->sense_data, sense_ptr, imin(XS_SNSLEN(xs),\ slen)); \ if (slen < (xs)->sense_len) \ (xs)->sense_resid = (xs)->sense_len - slen; \ } while (0); #define XS_SENSE_VALID(xs) (((xs)->ccb_h.status & CAM_AUTOSNS_VALID) != 0) #define DEFAULT_FRAMESIZE(isp) isp->isp_osinfo.framesize #define DEFAULT_EXEC_THROTTLE(isp) isp->isp_osinfo.exec_throttle #define GET_DEFAULT_ROLE(isp, chan) \ (IS_FC(isp)? ISP_FC_PC(isp, chan)->def_role : ISP_SPI_PC(isp, chan)->def_role) #define SET_DEFAULT_ROLE(isp, chan, val) \ if (IS_FC(isp)) { \ ISP_FC_PC(isp, chan)->def_role = val; \ } else { \ ISP_SPI_PC(isp, chan)->def_role = val; \ } #define DEFAULT_IID(isp, chan) isp->isp_osinfo.pc.spi[chan].iid #define DEFAULT_LOOPID(x, chan) isp->isp_osinfo.pc.fc[chan].default_id #define DEFAULT_NODEWWN(isp, chan) isp_default_wwn(isp, chan, 0, 1) #define DEFAULT_PORTWWN(isp, chan) isp_default_wwn(isp, chan, 0, 0) #define ACTIVE_NODEWWN(isp, chan) isp_default_wwn(isp, chan, 1, 1) #define ACTIVE_PORTWWN(isp, chan) isp_default_wwn(isp, chan, 1, 0) #if BYTE_ORDER == BIG_ENDIAN #ifdef ISP_SBUS_SUPPORTED #define ISP_IOXPUT_8(isp, s, d) *(d) = s #define ISP_IOXPUT_16(isp, s, d) \ *(d) = (isp->isp_bustype == ISP_BT_SBUS)? s : bswap16(s) #define ISP_IOXPUT_32(isp, s, d) \ *(d) = (isp->isp_bustype == ISP_BT_SBUS)? s : bswap32(s) #define ISP_IOXGET_8(isp, s, d) d = (*((uint8_t *)s)) #define ISP_IOXGET_16(isp, s, d) \ d = (isp->isp_bustype == ISP_BT_SBUS)? \ *((uint16_t *)s) : bswap16(*((uint16_t *)s)) #define ISP_IOXGET_32(isp, s, d) \ d = (isp->isp_bustype == ISP_BT_SBUS)? \ *((uint32_t *)s) : bswap32(*((uint32_t *)s)) #else /* ISP_SBUS_SUPPORTED */ #define ISP_IOXPUT_8(isp, s, d) *(d) = s #define ISP_IOXPUT_16(isp, s, d) *(d) = bswap16(s) #define ISP_IOXPUT_32(isp, s, d) *(d) = bswap32(s) #define ISP_IOXGET_8(isp, s, d) d = (*((uint8_t *)s)) #define ISP_IOXGET_16(isp, s, d) d = bswap16(*((uint16_t *)s)) #define ISP_IOXGET_32(isp, s, d) d = bswap32(*((uint32_t *)s)) #endif #define ISP_SWIZZLE_NVRAM_WORD(isp, rp) *rp = bswap16(*rp) #define ISP_SWIZZLE_NVRAM_LONG(isp, rp) *rp = bswap32(*rp) #define ISP_IOZGET_8(isp, s, d) d = (*((uint8_t *)s)) #define ISP_IOZGET_16(isp, s, d) d = (*((uint16_t *)s)) #define ISP_IOZGET_32(isp, s, d) d = (*((uint32_t *)s)) #define ISP_IOZPUT_8(isp, s, d) *(d) = s #define ISP_IOZPUT_16(isp, s, d) *(d) = s #define ISP_IOZPUT_32(isp, s, d) *(d) = s #else #define ISP_IOXPUT_8(isp, s, d) *(d) = s #define ISP_IOXPUT_16(isp, s, d) *(d) = s #define ISP_IOXPUT_32(isp, s, d) *(d) = s #define ISP_IOXGET_8(isp, s, d) d = *(s) #define ISP_IOXGET_16(isp, s, d) d = *(s) #define ISP_IOXGET_32(isp, s, d) d = *(s) #define ISP_SWIZZLE_NVRAM_WORD(isp, rp) #define ISP_SWIZZLE_NVRAM_LONG(isp, rp) #define ISP_IOZPUT_8(isp, s, d) *(d) = s #define ISP_IOZPUT_16(isp, s, d) *(d) = bswap16(s) #define ISP_IOZPUT_32(isp, s, d) *(d) = bswap32(s) #define ISP_IOZGET_8(isp, s, d) d = (*((uint8_t *)(s))) #define ISP_IOZGET_16(isp, s, d) d = bswap16(*((uint16_t *)(s))) #define ISP_IOZGET_32(isp, s, d) d = bswap32(*((uint32_t *)(s))) #endif #define ISP_SWAP16(isp, s) bswap16(s) #define ISP_SWAP32(isp, s) bswap32(s) /* * Includes of common header files */ #include #include #include /* * isp_osinfo definiitions && shorthand */ #define SIMQFRZ_RESOURCE 0x1 #define SIMQFRZ_LOOPDOWN 0x2 #define SIMQFRZ_TIMED 0x4 #define isp_dev isp_osinfo.dev /* * prototypes for isp_pci && isp_freebsd to share */ extern int isp_attach(ispsoftc_t *); extern int isp_detach(ispsoftc_t *); extern void isp_uninit(ispsoftc_t *); extern uint64_t isp_default_wwn(ispsoftc_t *, int, int, int); /* * driver global data */ extern int isp_announced; extern int isp_fabric_hysteresis; extern int isp_loop_down_limit; extern int isp_gone_device_time; extern int isp_quickboot_time; extern int isp_autoconfig; /* * Platform private flags */ #define ISP_SPRIV_ERRSET 0x1 #define ISP_SPRIV_TACTIVE 0x2 #define ISP_SPRIV_DONE 0x8 #define ISP_SPRIV_WPEND 0x10 #define XS_S_TACTIVE(sccb) (sccb)->ccb_h.spriv_field0 |= ISP_SPRIV_TACTIVE #define XS_C_TACTIVE(sccb) (sccb)->ccb_h.spriv_field0 &= ~ISP_SPRIV_TACTIVE #define XS_TACTIVE_P(sccb) ((sccb)->ccb_h.spriv_field0 & ISP_SPRIV_TACTIVE) #define XS_CMD_S_DONE(sccb) (sccb)->ccb_h.spriv_field0 |= ISP_SPRIV_DONE #define XS_CMD_C_DONE(sccb) (sccb)->ccb_h.spriv_field0 &= ~ISP_SPRIV_DONE #define XS_CMD_DONE_P(sccb) ((sccb)->ccb_h.spriv_field0 & ISP_SPRIV_DONE) #define XS_CMD_S_WPEND(sccb) (sccb)->ccb_h.spriv_field0 |= ISP_SPRIV_WPEND #define XS_CMD_C_WPEND(sccb) (sccb)->ccb_h.spriv_field0 &= ~ISP_SPRIV_WPEND #define XS_CMD_WPEND_P(sccb) ((sccb)->ccb_h.spriv_field0 & ISP_SPRIV_WPEND) #define XS_CMD_S_CLEAR(sccb) (sccb)->ccb_h.spriv_field0 = 0 /* * Platform Library Functions */ void isp_prt(ispsoftc_t *, int level, const char *, ...) __printflike(3, 4); void isp_xs_prt(ispsoftc_t *, XS_T *, int level, const char *, ...) __printflike(4, 5); uint64_t isp_nanotime_sub(struct timespec *, struct timespec *); int isp_mbox_acquire(ispsoftc_t *); void isp_mbox_wait_complete(ispsoftc_t *, mbreg_t *); void isp_mbox_notify_done(ispsoftc_t *); void isp_mbox_release(ispsoftc_t *); int isp_fc_scratch_acquire(ispsoftc_t *, int); int isp_mstohz(int); void isp_platform_intr(void *); void isp_common_dmateardown(ispsoftc_t *, struct ccb_scsiio *, uint32_t); /* * Platform Version specific defines */ #define BUS_DMA_ROOTARG(x) bus_get_dma_tag(x) #define isp_dma_tag_create(a, b, c, d, e, f, g, h, i, j, k, z) \ bus_dma_tag_create(a, b, c, d, e, f, g, h, i, j, k, \ busdma_lock_mutex, &isp->isp_osinfo.lock, z) #define isp_setup_intr bus_setup_intr #define isp_sim_alloc(a, b, c, d, e, f, g, h) \ cam_sim_alloc(a, b, c, d, e, &(d)->isp_osinfo.lock, f, g, h) /* Should be BUS_SPACE_MAXSIZE, but MAXPHYS is larger than BUS_SPACE_MAXSIZE */ #define ISP_NSEGS ((MAXPHYS / PAGE_SIZE) + 1) #define ISP_PATH_PRT(i, l, p, ...) \ if ((l) == ISP_LOGALL || ((l)& (i)->isp_dblev) != 0) { \ xpt_print(p, __VA_ARGS__); \ } /* * Platform specific inline functions */ /* * ISP General Library functions */ #include #endif /* _ISP_FREEBSD_H */ Index: stable/9/sys/dev/isp/ispvar.h =================================================================== --- stable/9/sys/dev/isp/ispvar.h (revision 237207) +++ stable/9/sys/dev/isp/ispvar.h (revision 237208) @@ -1,1178 +1,1187 @@ /* $FreeBSD$ */ /*- * Copyright (c) 1997-2009 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 #endif #ifdef __FreeBSD__ #include #include #endif #ifdef __linux__ #include "isp_stds.h" #include "ispmbox.h" #endif #ifdef __svr4__ #include "isp_stds.h" #include "ispmbox.h" #endif #define ISP_CORE_VERSION_MAJOR 7 #define ISP_CORE_VERSION_MINOR 0 /* * Vector for bus specific code to provide specific services. */ typedef struct ispsoftc ispsoftc_t; struct ispmdvec { int (*dv_rd_isr) (ispsoftc_t *, uint32_t *, uint16_t *, uint16_t *); uint32_t (*dv_rd_reg) (ispsoftc_t *, int); void (*dv_wr_reg) (ispsoftc_t *, int, uint32_t); int (*dv_mbxdma) (ispsoftc_t *); int (*dv_dmaset) (ispsoftc_t *, XS_T *, void *); void (*dv_dmaclr) (ispsoftc_t *, XS_T *, uint32_t); void (*dv_reset0) (ispsoftc_t *); void (*dv_reset1) (ispsoftc_t *); void (*dv_dregs) (ispsoftc_t *, const char *); const void * dv_ispfw; /* ptr to f/w */ uint16_t dv_conf1; uint16_t dv_clock; /* clock frequency */ }; /* * Overall parameters */ #define MAX_TARGETS 16 #ifndef MAX_FC_TARG #define MAX_FC_TARG 512 #endif #define ISP_MAX_TARGETS(isp) (IS_FC(isp)? MAX_FC_TARG : MAX_TARGETS) #define ISP_MAX_LUNS(isp) (isp)->isp_maxluns /* * 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) \ (*(isp)->isp_mdvec->dv_dmaset)((isp), (xs), (req)) #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) (((uint8_t *)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, -1); \ ISP_WRITE(isp, isp->isp_rqstinrp, nxti); \ isp->isp_reqidx = nxti #define ISP_SYNC_REQUEST(isp) \ MEMORYBARRIER(isp, SYNC_REQUEST, isp->isp_reqidx, QENTRY_LEN, -1); \ isp->isp_reqidx = ISP_NXT_QENTRY(isp->isp_reqidx, RQUEST_QUEUE_LEN(isp)); \ ISP_WRITE(isp, isp->isp_rqstinrp, isp->isp_reqidx) /* * SCSI Specific Host Adapter Parameters- per bus, per target */ typedef struct { uint32_t : 8, update : 1, sendmarker : 1, role : 2, 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_ptisp : 1, isp_ultramode : 1, isp_diffmode : 1, isp_lvdmode : 1, isp_fast_mttr : 1, /* fast sram */ isp_initiator_id : 4, isp_async_data_setup : 4; uint16_t isp_selection_timeout; uint16_t isp_max_queue_depth; uint8_t isp_tag_aging; uint8_t isp_bus_reset_delay; uint8_t isp_retry_count; uint8_t isp_retry_delay; struct { uint32_t exc_throttle : 8, : 1, dev_enable : 1, /* ignored */ dev_update : 1, dev_refresh : 1, actv_offset : 4, goal_offset : 4, nvrm_offset : 4; uint8_t actv_period; /* current sync period */ uint8_t goal_period; /* goal sync period */ uint8_t nvrm_period; /* nvram sync period */ uint16_t actv_flags; /* current device flags */ uint16_t goal_flags; /* goal device flags */ uint16_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 */ /* These are for non-2K Login Firmware cards */ #define FL_ID 0x7e /* FL_Port Special ID */ #define SNS_ID 0x80 /* SNS Server Special ID */ #define NPH_MAX 0xfe /* Use this handle for the base for multi-id firmware SNS logins */ #define NPH_SNS_HDLBASE 0x400 /* 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_FABRIC_CTLR 0x7FD /* Fabric Controller (0xFFFFFD) */ #define NPH_FL_ID 0x7FE /* F Port Special ID (0xFFFFFE) */ #define NPH_IP_BCST 0x7ff /* IP Broadcast Special ID (0xFFFFFF) */ #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 /* * Limit for (2K login) N-port handle amounts */ #define MAX_NPORT_HANDLE 2048 /* * Special Constants */ #define INI_NONE ((uint64_t) 0) #define ISP_NOCHAN 0xff /* * Special Port IDs */ #define MANAGEMENT_PORT_ID 0xFFFFFA #define SNS_PORT_ID 0xFFFFFC #define FABRIC_PORT_ID 0xFFFFFE #define PORT_ANY 0xFFFFFF #define PORT_NONE 0 #define DOMAIN_CONTROLLER_BASE 0xFFFC00 #define DOMAIN_CONTROLLER_END 0xFFFCFF /* * Command Handles * * Most QLogic initiator or target have 32 bit handles associated with them. * We want to have a quick way to index back and forth between a local SCSI * command context and what the firmware is passing back to us. We also * want to avoid working on stale information. This structure handles both * at the expense of some local memory. * * The handle is architected thusly: * * 0 means "free handle" * bits 0..12 index commands * bits 13..15 bits index usage * bits 16..31 contain a rolling sequence * * */ typedef struct { void * cmd; /* associated command context */ uint32_t handle; /* handle associated with this command */ } isp_hdl_t; #define ISP_HANDLE_FREE 0x00000000 #define ISP_HANDLE_CMD_MASK 0x00001fff #define ISP_HANDLE_USAGE_MASK 0x0000e000 #define ISP_HANDLE_USAGE_SHIFT 13 #define ISP_H2HT(hdl) ((hdl & ISP_HANDLE_USAGE_MASK) >> ISP_HANDLE_USAGE_SHIFT) # define ISP_HANDLE_NONE 0 # define ISP_HANDLE_INITIATOR 1 # define ISP_HANDLE_TARGET 2 #define ISP_HANDLE_SEQ_MASK 0xffff0000 #define ISP_HANDLE_SEQ_SHIFT 16 #define ISP_H2SEQ(hdl) ((hdl & ISP_HANDLE_SEQ_MASK) >> ISP_HANDLE_SEQ_SHIFT) #define ISP_VALID_INI_HANDLE(c, hdl) \ (ISP_H2HT(hdl) == ISP_HANDLE_INITIATOR && (hdl & ISP_HANDLE_CMD_MASK) < (c)->isp_maxcmds && \ ISP_H2SEQ(hdl) == ISP_H2SEQ((c)->isp_xflist[hdl & ISP_HANDLE_CMD_MASK].handle)) #ifdef ISP_TARGET_MODE #define ISP_VALID_TGT_HANDLE(c, hdl) \ (ISP_H2HT(hdl) == ISP_HANDLE_TARGET && (hdl & ISP_HANDLE_CMD_MASK) < (c)->isp_maxcmds && \ ISP_H2SEQ(hdl) == ISP_H2SEQ((c)->isp_tgtlist[hdl & ISP_HANDLE_CMD_MASK].handle)) #define ISP_VALID_HANDLE(c, hdl) \ (ISP_VALID_INI_HANDLE((c), hdl) || ISP_VALID_TGT_HANDLE((c), hdl)) #else #define ISP_VALID_HANDLE ISP_VALID_INI_HANDLE #endif #define ISP_BAD_HANDLE_INDEX 0xffffffff /* * 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_dev_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_dev_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 dev_map_idx * value. */ typedef struct { /* * This is the handle that the firmware needs in order for us to * send commands to the device. For pre-24XX cards, this would be * the 'loopid'. */ uint16_t handle; /* * The dev_map_idx, if nonzero, is the system virtual target ID (+1) * as a cross-reference with the isp_dev_map. * * A device is 'autologin' if the firmware automatically logs into * it (re-logins as needed). Basically, local private loop devices. * * The state is the current state of this entry. * * Role is Initiator, Target, Both * * Portid is obvious, as are node && port WWNs. The new_role and * new_portid is for when we are pending a change. * * The 'target_mode' tag means that this entry arrived via a * target mode command and is immune from normal flushing rules. * You should also never see anything with an initiator role * with this set. */ uint16_t dev_map_idx : 12, autologin : 1, /* F/W does PLOGI/PLOGO */ state : 3; uint32_t reserved : 5, target_mode : 1, roles : 2, portid : 24; uint32_t dirty : 1, /* commands have been run */ new_reserved : 5, new_roles : 2, new_portid : 24; uint64_t node_wwn; uint64_t port_wwn; uint32_t gone_timer; } fcportdb_t; #define FC_PORTDB_STATE_NIL 0 #define FC_PORTDB_STATE_PROBATIONAL 1 #define FC_PORTDB_STATE_DEAD 2 #define FC_PORTDB_STATE_CHANGED 3 #define FC_PORTDB_STATE_NEW 4 #define FC_PORTDB_STATE_PENDING_VALID 5 #define FC_PORTDB_STATE_ZOMBIE 6 #define FC_PORTDB_STATE_VALID 7 /* * FC card specific information * * This structure is replicated across multiple channels for multi-id * capapble chipsets, with some entities different on a per-channel basis. */ typedef struct { uint32_t link_active : 1, npiv_fabric : 1, inorder : 1, sendmarker : 1, role : 2, isp_gbspeed : 4, isp_loopstate : 4, /* Current Loop State */ isp_fwstate : 4, /* ISP F/W state */ isp_topo : 3, /* Connection Type */ loop_seen_once : 1; uint32_t : 8, isp_portid : 24; /* S_ID */ uint16_t isp_fwoptions; uint16_t isp_xfwoptions; uint16_t isp_zfwoptions; uint16_t isp_loopid; /* hard loop id */ uint16_t isp_sns_hdl; /* N-port handle for SNS */ uint16_t isp_lasthdl; /* only valid for channel 0 */ uint16_t isp_maxalloc; uint8_t isp_retry_delay; uint8_t isp_retry_count; /* * Current active WWNN/WWPN */ uint64_t isp_wwnn; uint64_t isp_wwpn; /* * NVRAM WWNN/WWPN */ uint64_t isp_wwnn_nvram; uint64_t isp_wwpn_nvram; /* * Our Port Data Base */ fcportdb_t portdb[MAX_FC_TARG]; /* * This maps system virtual 'target' id to a portdb entry. * * The mapping function is to take any non-zero entry and * subtract one to get the portdb index. This means that * entries which are zero are unmapped (i.e., don't exist). */ uint16_t isp_dev_map[MAX_FC_TARG]; #ifdef ISP_TARGET_MODE /* * This maps N-Port Handle to portdb entry so we * don't have to search for every incoming command. * * The mapping function is to take any non-zero entry and * subtract one to get the portdb index. This means that * entries which are zero are unmapped (i.e., don't exist). */ uint16_t isp_tgt_map[MAX_NPORT_HANDLE]; #endif /* * Scratch DMA mapped in area to fetch Port Database stuff, etc. */ void * isp_scratch; XS_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_LOOP 3 #define LOOP_LSCAN_DONE 4 #define LOOP_SCANNING_FABRIC 5 #define LOOP_FSCAN_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 */ 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 */ uint16_t isp_fwrev[3]; /* Loaded F/W revision */ uint16_t isp_maxcmds; /* max possible I/O cmds */ uint8_t isp_type; /* HBA Chip Type */ uint8_t isp_revision; /* HBA Chip H/W Revision */ uint32_t isp_maxluns; /* maximum luns supported */ uint32_t isp_clock : 8, /* input clock */ : 4, isp_port : 1, /* 23XX/24XX only */ isp_open : 1, /* opened (ioctl) */ isp_bustype : 1, /* SBus or PCI */ isp_loaded_fw : 1, /* loaded firmware */ isp_dblev : 16; /* debug log mask */ uint16_t isp_fwattr; /* firmware attributes */ uint16_t isp_nchan; /* number of channels */ uint32_t isp_confopts; /* config options */ uint32_t isp_rqstinrp; /* register for REQINP */ uint32_t isp_rqstoutrp; /* register for REQOUTP */ uint32_t isp_respinrp; /* register for RESINP */ uint32_t isp_respoutrp; /* register for RESOUTP */ /* * Instrumentation */ uint64_t isp_intcnt; /* total int count */ uint64_t isp_intbogus; /* spurious int count */ uint64_t isp_intmboxc; /* mbox completions */ uint64_t isp_intoasync; /* other async */ uint64_t isp_rsltccmplt; /* CMDs on result q */ uint64_t isp_fphccmplt; /* CMDs via fastpost */ uint16_t isp_rscchiwater; uint16_t isp_fpcchiwater; NANOTIME_T isp_init_time; /* time were last initialized */ /* * Volatile state */ volatile uint32_t : 8, : 2, isp_dead : 1, : 1, isp_mboxbsy : 1, /* mailbox command active */ isp_state : 3, isp_nactive : 16; /* how many commands active */ volatile mbreg_t isp_curmbx; /* currently active mailbox command */ volatile uint32_t isp_reqodx; /* index of last ISP pickup */ volatile uint32_t isp_reqidx; /* index of next request */ volatile uint32_t isp_residx; /* index of next result */ volatile uint32_t isp_resodx; /* index of next result */ volatile uint32_t isp_obits; /* mailbox command output */ volatile uint32_t isp_serno; /* rolling serial number */ volatile uint16_t isp_mboxtmp[MAILBOX_STORAGE]; volatile uint16_t isp_lastmbxcmd; /* last mbox command sent */ volatile uint16_t isp_mbxwrk0; volatile uint16_t isp_mbxwrk1; volatile uint16_t isp_mbxwrk2; volatile uint16_t isp_mbxwrk8; volatile uint16_t isp_seqno; /* running sequence number */ void * isp_mbxworkp; /* * Active commands are stored here, indexed by handle functions. */ isp_hdl_t *isp_xflist; isp_hdl_t *isp_xffree; #ifdef ISP_TARGET_MODE /* * Active target commands are stored here, indexed by handle functions. */ isp_hdl_t *isp_tgtlist; isp_hdl_t *isp_tgtfree; #endif /* * request/result queue pointers and DMA handles for them. */ void * isp_rquest; void * isp_result; XS_DMA_ADDR_T isp_rquest_dma; XS_DMA_ADDR_T isp_result_dma; #ifdef ISP_TARGET_MODE /* for 24XX only */ void * isp_atioq; XS_DMA_ADDR_T isp_atioq_dma; #endif }; #define SDPARAM(isp, chan) (&((sdparam *)(isp)->isp_param)[(chan)]) #define FCPARAM(isp, chan) (&((fcparam *)(isp)->isp_param)[(chan)]) #define ISP_SET_SENDMARKER(isp, chan, val) \ if (IS_FC(isp)) { \ FCPARAM(isp, chan)->sendmarker = val; \ } else { \ SDPARAM(isp, chan)->sendmarker = val; \ } #define ISP_TST_SENDMARKER(isp, chan) \ (IS_FC(isp)? \ FCPARAM(isp, chan)->sendmarker != 0 : \ SDPARAM(isp, chan)->sendmarker != 0) /* * ISP Driver Run States */ #define ISP_NILSTATE 0 #define ISP_CRASHED 1 #define ISP_RESETSTATE 2 #define ISP_INITSTATE 3 #define ISP_RUNSTATE 4 /* * 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_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) */ /* * For each channel, the outer layers should know what role that channel * will take: ISP_ROLE_NONE, ISP_ROLE_INITIATOR, ISP_ROLE_TARGET, * ISP_ROLE_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 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_TARGET 0x1 #define ISP_ROLE_INITIATOR 0x2 #define ISP_ROLE_BOTH (ISP_ROLE_TARGET|ISP_ROLE_INITIATOR) #define ISP_ROLE_EITHER ISP_ROLE_BOTH #ifndef ISP_DEFAULT_ROLES +/* + * Counterintuitively, we prefer to default to role 'none' + * if we are enable target mode support. This gives us the + * maximum flexibility as to which port will do what. + */ +#ifdef ISP_TARGET_MODE +#define ISP_DEFAULT_ROLES ISP_ROLE_NONE +#else #define ISP_DEFAULT_ROLES ISP_ROLE_INITIATOR +#endif #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 ISP_HA_FC_2500 0x70 #define IS_SCSI(isp) (isp->isp_type & ISP_HA_SCSI) #define IS_1020(isp) (isp->isp_type < ISP_HA_SCSI_1240) #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 && \ (isp)->isp_type < ISP_HA_FC_2400) #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) #define IS_25XX(isp) ((isp)->isp_type >= ISP_HA_FC_2500) /* * DMA related macros */ #define DMA_WD3(x) (((uint16_t)(((uint64_t)x) >> 48)) & 0xffff) #define DMA_WD2(x) (((uint16_t)(((uint64_t)x) >> 32)) & 0xffff) #define DMA_WD1(x) ((uint16_t)((x) >> 16) & 0xffff) #define DMA_WD0(x) ((uint16_t)((x) & 0xffff)) #define DMA_LO32(x) ((uint32_t) (x)) #define DMA_HI32(x) ((uint32_t)(((uint64_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(ispsoftc_t *, int); /* * Initialize Hardware to known state */ void isp_init(ispsoftc_t *); /* * Reset the ISP and call completion for any orphaned commands. */ void isp_reinit(ispsoftc_t *, int); /* * 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(ispsoftc_t *, uint32_t, uint16_t, uint16_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 locks may be released while this function is called. * * ... ISPCTL_RESET_BUS, int channel); * Reset BUS on this channel * ... ISPCTL_RESET_DEV, int channel, int target); * Reset Device on this channel at this target. * ... ISPCTL_ABORT_CMD, XS_T *xs); * Abort active transaction described by xs. * ... IPCTL_UPDATE_PARAMS); * Update any operating parameters (speed, etc.) * ... ISPCTL_FCLINK_TEST, int channel); * Test FC link status on this channel * ... ISPCTL_SCAN_FABRIC, int channel); * Scan fabric on this channel * ... ISPCTL_SCAN_LOOP, int channel); * Scan local loop on this channel * ... ISPCTL_PDB_SYNC, int channel); * Synchronize port database on this channel * ... ISPCTL_SEND_LIP, int channel); * Send a LIP on this channel * ... ISPCTL_GET_NAMES, int channel, int np, uint64_t *wwnn, uint64_t *wwpn) * Get a WWNN/WWPN for this N-port handle on this channel * ... ISPCTL_RUN_MBOXCMD, mbreg_t *mbp) * Run this mailbox command * ... ISPCTL_GET_PDB, int channel, int nphandle, isp_pdb_t *pdb) * Get PDB on this channel for this N-port handle * ... ISPCTL_PLOGX, isp_plcmd_t *) * Performa a port login/logout * * 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, ISPCTL_RESET_DEV, ISPCTL_ABORT_CMD, ISPCTL_UPDATE_PARAMS, ISPCTL_FCLINK_TEST, ISPCTL_SCAN_FABRIC, ISPCTL_SCAN_LOOP, ISPCTL_PDB_SYNC, ISPCTL_SEND_LIP, ISPCTL_GET_NAMES, ISPCTL_RUN_MBOXCMD, ISPCTL_GET_PDB, ISPCTL_PLOGX } ispctl_t; int isp_control(ispsoftc_t *, ispctl_t, ...); /* * Platform Dependent to Internal to External Control Function */ typedef enum { ISPASYNC_NEW_TGT_PARAMS, /* SPI New Target Parameters */ ISPASYNC_BUS_RESET, /* All Bus Was Reset */ ISPASYNC_LOOP_DOWN, /* FC Loop Down */ ISPASYNC_LOOP_UP, /* FC Loop Up */ ISPASYNC_LIP, /* FC LIP Received */ ISPASYNC_LOOP_RESET, /* FC Loop Reset Received */ ISPASYNC_CHANGE_NOTIFY, /* FC Change Notification */ ISPASYNC_DEV_ARRIVED, /* FC Device Arrived */ ISPASYNC_DEV_CHANGED, /* FC Device Changed */ ISPASYNC_DEV_STAYED, /* FC Device Stayed */ ISPASYNC_DEV_GONE, /* FC Device Departure */ ISPASYNC_TARGET_NOTIFY, /* All target async notification */ ISPASYNC_TARGET_ACTION, /* All target action requested */ ISPASYNC_FW_CRASH, /* All Firmware has crashed */ ISPASYNC_FW_RESTARTED /* All Firmware has been restarted */ } ispasync_t; void isp_async(ispsoftc_t *, ispasync_t, ...); #define ISPASYNC_CHANGE_PDB 0 #define ISPASYNC_CHANGE_SNS 1 #define ISPASYNC_CHANGE_OTHER 2 /* * Platform Independent Error Prinout */ void isp_prt_endcmd(ispsoftc_t *, XS_T *); /* * Platform Dependent Error and Debug Printout * * Two required functions for each platform must be provided: * * void isp_prt(ispsoftc_t *, int level, const char *, ...) * void isp_xs_prt(ispsoftc_t *, XS_T *, int level, const char *, ...) * * but due to compiler differences on different platforms this won't be * formally defined here. Instead, they go in each platform definition file. */ #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_LOGSANCFG 0x100 /* log SAN configuration */ #define ISP_LOG_CWARN 0x200 /* log SCSI command "warnings" (e.g., check conditions) */ #define ISP_LOGTINFO 0x1000 /* log informational messages (target mode) */ #define ISP_LOGTDEBUG0 0x2000 /* log simple debug messages (target mode) */ #define ISP_LOGTDEBUG1 0x4000 /* log intermediate debug messages (target) */ #define ISP_LOGTDEBUG2 0x8000 /* 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: * * * ISP_FC_SCRLEN FC scratch area DMA length * * ISP_MEMZERO(dst, src) platform zeroing function * ISP_MEMCPY(dst, src, count) platform copying function * ISP_SNPRINTF(buf, bufsize, fmt, ...) snprintf * ISP_DELAY(usecs) microsecond spindelay function * ISP_SLEEP(isp, usecs) microsecond sleep function * * ISP_INLINE ___inline or not- depending on how * good your debugger is * ISP_MIN shorthand for ((a) < (b))? (a) : (b) * * NANOTIME_T nanosecond time type * * GET_NANOTIME(NANOTIME_T *) get current nanotime. * * GET_NANOSEC(NANOTIME_T *) get uint64_t from NANOTIME_T * * NANOTIME_SUB(NANOTIME_T *, NANOTIME_T *) * subtract two NANOTIME_T values * * MAXISPREQUEST(ispsoftc_t *) maximum request queue size * for this particular board type * * MEMORYBARRIER(ispsoftc_t *, barrier_type, offset, size, chan) * * 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(ispsoftc_t *) acquire lock on mailbox regs * MBOX_WAIT_COMPLETE(ispsoftc_t *, mbreg_t *) wait for cmd to be done * MBOX_NOTIFY_COMPLETE(ispsoftc_t *) notification of mbox cmd donee * MBOX_RELEASE(ispsoftc_t *) release lock on mailbox regs * * FC_SCRATCH_ACQUIRE(ispsoftc_t *, chan) acquire lock on FC scratch area * return -1 if you cannot * FC_SCRATCH_RELEASE(ispsoftc_t *, chan) 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_DMA_ADDR_T Platform PCI DMA Address Type * XS_GET_DMA_SEG(..) Get 32 bit dma segment list value * XS_GET_DMA64_SEG(..) Get 64 bit dma segment list value * 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_GET_RESID(xs) gets the current residual count * XS_GET_RESID(xs, resid) sets 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_SNSASC(xs) dereferences XS_SNSP to get the current stored Additional Sense Code * XS_SNSASCQ(xs) dereferences XS_SNSP to get the current stored Additional Sense Code Qualifier * 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, len) save sense data * * XS_SENSE_VALID(xs) indicates whether sense is valid * * DEFAULT_FRAMESIZE(ispsoftc_t *) Default Frame Size * DEFAULT_EXEC_THROTTLE(ispsoftc_t *) Default Execution Throttle * * GET_DEFAULT_ROLE(ispsoftc_t *, int) Get Default Role for a channel * SET_DEFAULT_ROLE(ispsoftc_t *, int, int) Set Default Role for a channel * DEFAULT_IID(ispsoftc_t *, int) Default SCSI initiator ID * DEFAULT_LOOPID(ispsoftc_t *, int) Default FC Loop ID * * 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. * * DEFAULT_NODEWWN(ispsoftc_t *, chan) Default FC Node WWN to use * DEFAULT_PORTWWN(ispsoftc_t *, chan) Default FC Port WWN to use * * These defines are hooks to allow the setting of node and * port WWNs when NVRAM cannot be read or is to be overriden. * * ACTIVE_NODEWWN(ispsoftc_t *, chan) FC Node WWN to use * ACTIVE_PORTWWN(ispsoftc_t *, chan) FC Port WWN to use * * After NVRAM is read, these will be invoked to get the * node and port WWNs that will actually be used for this * channel. * * * ISP_IOXPUT_8(ispsoftc_t *, uint8_t srcval, uint8_t *dstptr) * ISP_IOXPUT_16(ispsoftc_t *, uint16_t srcval, uint16_t *dstptr) * ISP_IOXPUT_32(ispsoftc_t *, uint32_t srcval, uint32_t *dstptr) * * ISP_IOXGET_8(ispsoftc_t *, uint8_t *srcptr, uint8_t dstrval) * ISP_IOXGET_16(ispsoftc_t *, uint16_t *srcptr, uint16_t dstrval) * ISP_IOXGET_32(ispsoftc_t *, uint32_t *srcptr, uint32_t dstrval) * * ISP_SWIZZLE_NVRAM_WORD(ispsoftc_t *, uint16_t *) * ISP_SWIZZLE_NVRAM_LONG(ispsoftc_t *, uint32_t *) * ISP_SWAP16(ispsoftc_t *, uint16_t srcval) * ISP_SWAP32(ispsoftc_t *, uint32_t srcval) */ #ifdef ISP_TARGET_MODE /* * The functions below are for the publicly available * target mode functions that are internal to the Qlogic driver. */ /* * This function handles new response queue entry appropriate for target mode. */ int isp_target_notify(ispsoftc_t *, void *, uint32_t *); /* * This function externalizes the ability to acknowledge an Immediate Notify request. */ int isp_notify_ack(ispsoftc_t *, void *); /* * This function externalized acknowledging (success/fail) an ABTS frame */ int isp_acknak_abts(ispsoftc_t *, void *, int); /* * Enable/Disable/Modify a logical unit. * (softc, cmd, bus, tgt, lun, cmd_cnt, inotify_cnt) */ #define DFLT_CMND_CNT 0xfe /* unmonitored */ #define DFLT_INOT_CNT 0xfe /* unmonitored */ int isp_lun_cmd(ispsoftc_t *, int, int, int, int, int); /* * General request queue 'put' routine for target mode entries. */ int isp_target_put_entry(ispsoftc_t *isp, void *); /* * General routine to put back an ATIO entry- * used for replenishing f/w resource counts. * The argument is a pointer to a source ATIO * or ATIO2. */ int isp_target_put_atio(ispsoftc_t *, void *); /* * General routine to send a final CTIO for a command- used mostly for * local responses. */ int isp_endcmd(ispsoftc_t *, ...); #define ECMD_SVALID 0x100 #define ECMD_TERMINATE 0x200 /* * Handle an asynchronous event * * Return nonzero if the interrupt that generated this event has been dismissed. */ int isp_target_async(ispsoftc_t *, int, int); #endif #endif /* _ISPVAR_H */ Index: stable/9/sys/dev/isp =================================================================== --- stable/9/sys/dev/isp (revision 237207) +++ stable/9/sys/dev/isp (revision 237208) Property changes on: stable/9/sys/dev/isp ___________________________________________________________________ Added: svn:mergeinfo ## -0,0 +0,15 ## Merged /user/thompsa/usb/sys/dev/isp:r187190 Merged /head/sys:r236427 Merged /projects/largeSMP/sys/dev/isp:r221273-222812,222815-223757 Merged /projects/multi-fibv6/head/sys/dev/isp:r230929-231848 Merged /user/jimharris/isci/sys/dev/isp:r228377-230794 Merged /projects/cambria/sys/dev/isp:r186008-186350 Merged /projects/head_mfi/sys/dev/isp:r227068,227574,227579-227580,227612,227905,228108,228208,228279,228310,228320,231988,232412-232414,232888,233016,233620 Merged /user/dfr/xenhvm/6/sys/dev/isp:r189304,189451 Merged /user/dfr/xenhvm/7/sys/dev/isp:r188574-189614 Merged /user/peter/kinfo/sys/dev/isp:r185413-185547 Merged /projects/quota64/sys/dev/isp:r184125-207707 Merged /user/piso/sys/dev/isp:r186543,186723,186725-186726,186742,186770-186771,186774,186777-186779,187984-187985,190555,190572,190589,190592,190614,190625,190830 Merged 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Merged /user/piso/ipfw/sys/dev/isp:r190918,190921,190923,190926 Merged /user/mav/ata/sys/dev/isp:r189793-190578 Index: stable/9/sys/dev =================================================================== --- stable/9/sys/dev (revision 237207) +++ stable/9/sys/dev (revision 237208) Property changes on: stable/9/sys/dev ___________________________________________________________________ Modified: svn:mergeinfo ## -0,0 +0,1 ## Merged /head/sys/dev:r236427 Index: stable/9/sys =================================================================== --- stable/9/sys (revision 237207) +++ stable/9/sys (revision 237208) Property changes on: stable/9/sys ___________________________________________________________________ Modified: svn:mergeinfo ## -0,0 +0,1 ## Merged /head/sys:r236427