xref: /freebsd/share/man/man4/scsi.4 (revision d5b0e70f7e04d971691517ce1304d86a1e367e2e)
1.\" Copyright (c) 1996
2.\"	Julian Elischer <julian@FreeBSD.org>.  All rights reserved.
3.\"
4.\" Redistribution and use in source and binary forms, with or without
5.\" modification, are permitted provided that the following conditions
6.\" are met:
7.\" 1. Redistributions of source code must retain the above copyright
8.\"    notice, this list of conditions and the following disclaimer.
9.\"
10.\" 2. Redistributions in binary form must reproduce the above copyright
11.\"    notice, this list of conditions and the following disclaimer in the
12.\"    documentation and/or other materials provided with the distribution.
13.\"
14.\" THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
15.\" ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
16.\" IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
17.\" ARE DISCLAIMED.  IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
18.\" FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
19.\" DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
20.\" OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
21.\" HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
22.\" LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
23.\" OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
24.\" SUCH DAMAGE.
25.\"
26.\" $FreeBSD$
27.Dd November 3, 2021
28.Dt CAM 4
29.Os
30.Sh NAME
31.Nm CAM
32.Nd Common Access Method Storage subsystem
33.Sh SYNOPSIS
34.Cd "device scbus"
35.Cd "device ada"
36.Cd "device cd"
37.Cd "device ch"
38.Cd "device da"
39.Cd "device pass"
40.Cd "device pt"
41.Cd "device sa"
42.Cd "options CAMDEBUG"
43.Cd "options CAM_DEBUG_BUS=-1"
44.Cd "options CAM_DEBUG_TARGET=-1"
45.Cd "options CAM_DEBUG_LUN=-1"
46.Cd "options CAM_DEBUG_COMPILE=CAM_DEBUG_INFO|CAM_DEBUG_CDB|CAM_DEBUG_PROBE"
47.Cd "options CAM_DEBUG_FLAGS=CAM_DEBUG_INFO|CAM_DEBUG_CDB"
48.Cd "options CAM_MAX_HIGHPOWER=4"
49.Cd "options SCSI_NO_SENSE_STRINGS"
50.Cd "options SCSI_NO_OP_STRINGS"
51.Cd "options SCSI_DELAY=8000"
52.Sh DESCRIPTION
53The
54.Nm
55subsystem provides a uniform and modular system for the implementation
56of drivers to control various
57.Tn SCSI ,
58.Tn ATA ,
59.Tn NVMe ,
60and
61.Tn MMC / SD
62devices, and to utilize different
63.Tn SCSI ,
64.Tn ATA ,
65.Tn NVMe ,
66and
67.Tn MMC / SD
68host adapters through host adapter drivers.
69When the system probes buses, it attaches any devices it finds to the
70appropriate drivers.
71The
72.Xr pass 4
73driver, if it is configured in the kernel, will attach to all devices.
74.Sh KERNEL CONFIGURATION
75There are a number of generic kernel configuration options for the
76.Nm
77subsystem:
78.Bl -tag -width SCSI_NO_SENSE_STRINGS
79.It Dv CAM_BOOT_DELAY
80Additional time to wait after the static parts of the kernel have run to allow
81for discovery of additional devices which may take time to connect,
82such as USB attached storage.
83.It Dv CAM_IOSCHED_DYNAMIC
84Enable dynamic decisions in the I/O scheduler based on hints and the current
85performance of the storage devices.
86.It Dv CAM_IO_STATS
87Enable collection of statistics for periph devices.
88.It Dv CAM_TEST_FAILURE
89Enable ability to simulate I/O failures.
90.It Dv CAMDEBUG
91This option compiles in all the
92.Nm
93debugging printf code.
94This will not actually
95cause any debugging information to be printed out when included by itself.
96See below for details.
97.It Dv "CAM_MAX_HIGHPOWER=4"
98This sets the maximum allowable number of concurrent "high power" commands.
99A "high power" command is a command that takes more electrical power than
100most to complete.
101An example of this is the
102.Tn SCSI
103START UNIT command.
104Starting a disk often takes significantly more electrical power than normal
105operation.
106This option allows the
107user to specify how many concurrent high power commands may be outstanding
108without overloading the power supply on his computer.
109.It Dv SCSI_NO_SENSE_STRINGS
110This eliminates text descriptions of each
111.Tn SCSI
112Additional Sense Code and Additional Sense Code Qualifier pair.
113Since this
114is a fairly large text database, eliminating it reduces the size of the
115kernel somewhat.
116This is primarily necessary for boot floppies and other
117low disk space or low memory space environments.
118In most cases, though,
119this should be enabled, since it speeds the interpretation of
120.Tn SCSI
121error messages.
122Do not let the "kernel bloat" zealots get to you -- leave
123the sense descriptions in your kernel!
124.It Dv SCSI_NO_OP_STRINGS
125This disables text descriptions of each
126.Tn SCSI
127opcode.
128This option, like the sense string option above, is primarily
129useful for environments like a boot floppy where kernel size is critical.
130Enabling this option for normal use is not recommended, since it slows
131debugging of
132.Tn SCSI
133problems.
134.It Dv SCSI_DELAY=8000
135This is the
136.Tn SCSI
137"bus settle delay."
138In
139.Nm ,
140it is specified in
141.Em milliseconds ,
142not seconds like the old
143.Tn SCSI
144layer used to do.
145When the kernel boots, it sends a bus reset to each
146.Tn SCSI
147bus to tell each device to reset itself to a default set of transfer
148negotiations and other settings.
149Most
150.Tn SCSI
151devices need some amount of time to recover from a bus reset.
152Newer disks
153may need as little as 100ms, while old, slow devices may need much longer.
154If the
155.Dv SCSI_DELAY
156is not specified, it defaults to 2 seconds.
157The minimum allowable value for
158.Dv SCSI_DELAY
159is "100", or 100ms.
160One special case is that if the
161.Dv SCSI_DELAY
162is set to 0, that will be taken to mean the "lowest possible value."
163In that case, the
164.Dv SCSI_DELAY
165will be reset to 100ms.
166.El
167.Pp
168All devices and buses support dynamic allocation so that
169an upper number of devices and controllers does not need to be configured;
170.Cd "device da"
171will suffice for any number of disk drivers.
172.Pp
173The devices are either
174.Em wired
175so they appear as a particular device unit or
176.Em counted
177so that they appear as the next available unused unit.
178.Pp
179Units are wired down by setting kernel environment hints.
180This is usually done either interactively from the
181.Xr loader 8 ,
182or automatically via the
183.Pa /boot/device.hints
184file.
185The basic syntax is:
186.Bd -literal -offset indent
187hint.device.unit.property="value"
188.Ed
189.Pp
190Individual
191.Nm
192bus numbers can be wired down to specific controllers with
193a config line similar to the following:
194.Bd -literal -offset indent
195hint.scbus.0.at="ahd1"
196.Ed
197.Pp
198This assigns
199.Nm
200bus number 0 to the
201.Em ahd1
202driver instance.
203For controllers supporting more than one bus, a particular bus can be assigned
204as follows:
205.Bd -literal -offset indent
206hint.scbus.0.at="ahc1"
207hint.scbus.0.bus="1"
208.Ed
209.Pp
210This assigns
211.Nm
212bus 0 to the bus 1 instance on
213.Em ahc1 .
214Peripheral drivers can be wired to a specific bus, target, and lun as so:
215.Bd -literal -offset indent
216hint.da.0.at="scbus0"
217hint.da.0.target="0"
218hint.da.0.unit="0"
219.Ed
220.Pp
221This assigns
222.Em da0
223to target 0, unit (lun) 0 of scbus 0.
224Omitting the target or unit hints will instruct
225.Nm
226to treat them as wildcards
227and use the first respective counted instances.
228These examples can be combined together to allow a peripheral device to be
229wired to any particular controller, bus, target, and/or unit instance.
230.Pp
231This also works with
232.Xr nvme 4
233drives as well.
234.Bd -literal -offset indent
235hint.nvme.4.at="pci7:0:0"
236hint.scbus.10.at="nvme4"
237hint.nda.10.at="scbus10"
238hint.nda.10.target="1"
239hint.nda.10.unit="12"
240hint.nda.11.at="scbus10"
241hint.nda.11.target="1"
242hint.nda.11.unit="2"
243.Ed
244.Pp
245This assigns the NVMe card living at PCI bus 7 slot 0 function 1 to scbus 10.
246The target for
247.Xr nda 4
248devices is always 1.
249The unit is the namespace identifier from the drive.
250The namespace id 1 is exported as
251.Em nda10
252and namespace id 2 is exported as
253.Em nda11 .
254.Pp
255For devices that provide a serial number, units may be wired to that serial
256number without regard where the drive is attached:
257.Bd -literal -offset indent
258hint.nda.3.sn="CY0AN07101120B12P"
259hint.da.44.sn="143282400011"
260hint.ada.2.sn="A065D591"
261.Ed
262wires
263.Em nda3 ,
264.Em da44 ,
265and
266.Em ada2
267to drives with the specified serial numbers.
268One need not specify an
269.Em at
270line when serial numbers are used.
271.Sh ADAPTERS
272The system allows common device drivers to work through many different
273types of adapters.
274The adapters take requests from the upper layers and do
275all IO between the
276.Tn SCSI ,
277.Tn ATA ,
278.Tn NVMe ,
279or
280.Tn MMC / SD
281bus and the system.
282The maximum size of a transfer is governed by the
283adapter.
284Most adapters can transfer 64KB in a single operation, however
285many can transfer larger amounts.
286.Sh TARGET MODE
287Some adapters support
288.Em target mode
289in which the system is capable of operating as a device, responding to
290operations initiated by another system.
291Target mode is supported for
292some adapters, but is not yet complete for this version of the
293.Nm
294.Tn SCSI
295subsystem.
296.Sh ARCHITECTURE
297The
298.Nm
299subsystem glues together the upper layers of the system to the storage devices.
300PERIPH devices accept storage requests from GEOM and other upper layers of the
301system and translates them into protocol requests.
302XPT (transport) dispatches these protocol requests to a SIM driver.
303A SIM driver takes protocol requests and translates them into hardware commands
304the host adapter understands to transfer the protocol requests, and data (if
305any) to the storage device.
306The CCB transports these requests around as messages.
307.Ss CAM
308The Common Access Method was a standard defined in the 1990s to talk to disk
309drives.
310.Fx
311is one of the few operating systems to fully implement this model.
312The interface between different parts of CAM is the CCB (or CAM Control Block).
313Each CCB has a standard header, which contains the type of request and dispatch
314information, and a command specific portion.
315A CAM Periph generates requests.
316The XPT layer dispatches these requests to the appropriate SIM.
317Some CCBs are sent directly to the SIM for immediate processing, while others
318are queued and complete when the I/O has finished.
319A SIM takes CCBs and translates them into hardware specific commands to push the
320SCSI CDB or other protocol control block to the peripheral, along with setting
321up the DMA for the associated data.
322.Ss Periph Devices
323A periph driver knows how to translate standard requests into protocol messages
324that a SIM can deliver to hardware.
325These requests can come from any upper layer source, but primarily come in via
326GEOM as a bio request.
327They can also come in directly from character device requests for tapes and pass
328through commands.
329.Pp
330Disk devices, or direct access (da) in CAM, are one type of peripheral.
331These devices present themselves to the kernel a device ending in
332.Dq da .
333Each protocol has a unique device name:
334.Bl -tag -width 4
335.It Xr da 4
336SCSI or SAS device, or devices that accept SCSI CDBs for I/O.
337.It Xr ada 4
338ATA or SATA device
339.It Xr nda 4
340NVME device
341.It Xr sdda 4
342An SD or MMC block storage device.
343.El
344.Pp
345Tape devices are called serial access
346.Po
347.Xr sa 4
348.Pc
349in CAM.
350They interface to the system via a character device and provide
351.Xr ioctl 2
352control for tape drives.
353.Pp
354The
355.Xr pass 4
356device will pass through CCB requests from userland to the SIM directly.
357The device is used to send commands other than read, write, trim or flush to a
358device.
359The
360.Xr camcontrol 8
361command uses this device.
362.Ss XPT drivers
363The transport driver connects the periph to the SIM.
364It is not configured separately.
365It is also responsible for device discovery for those SIM drivers that do not
366enumerate themselves.
367.Ss SIM driver
368SIM used to stand for SCSI Interface Module.
369Now it is just SIM because it understands protocols other than SCSI.
370There are two types of SIM drivers: virtual and physical.
371Physical SIMs are typically called host bus adapters (HBA), but not universally.
372Virtual SIM drivers are for communicating with virtual machine hosts.
373.Sh FILES
374see other
375.Nm
376device entries.
377.Sh DIAGNOSTICS
378An XPT_DEBUG CCB can be used to enable various amounts of tracing information
379on any specific bus/device from the list of options compiled into the kernel.
380There are currently seven debugging flags that may be compiled in and used:
381.Bl -tag -width CAM_DEBUG_SUBTRACE
382.It Dv CAM_DEBUG_INFO
383This flag enables general informational printfs for the device
384or devices in question.
385.It Dv CAM_DEBUG_TRACE
386This flag enables function-level command flow tracing i.e.,
387kernel printfs will happen at the entrance and exit of various functions.
388.It Dv CAM_DEBUG_SUBTRACE
389This flag enables debugging output internal to various functions.
390.It Dv CAM_DEBUG_CDB
391This flag will cause the kernel to print out all
392.Tn ATA
393and
394.Tn SCSI
395commands sent to a particular device or devices.
396.It Dv CAM_DEBUG_XPT
397This flag will enable command scheduler tracing.
398.It Dv CAM_DEBUG_PERIPH
399This flag will enable peripheral drivers messages.
400.It Dv CAM_DEBUG_PROBE
401This flag will enable devices probe process tracing.
402.El
403.Pp
404Some of these flags, most notably
405.Dv CAM_DEBUG_TRACE
406and
407.Dv CAM_DEBUG_SUBTRACE ,
408will produce kernel printfs in EXTREME numbers.
409.Pp
410Users can enable debugging from their kernel config file, by using
411the following kernel config options:
412.Bl -tag -width CAM_DEBUG_COMPILE
413.It Dv CAMDEBUG
414This builds into the kernel all possible
415.Nm
416debugging.
417.It Dv CAM_DEBUG_COMPILE
418This specifies support for which debugging flags described above
419should be built into the kernel.
420Flags may be ORed together if the user wishes to
421see printfs for multiple debugging levels.
422.It Dv CAM_DEBUG_FLAGS
423This sets the various debugging flags from a kernel config file.
424.It Dv CAM_DEBUG_BUS
425Specify a bus to debug.
426To debug all buses, set this to -1.
427.It Dv CAM_DEBUG_TARGET
428Specify a target to debug.
429To debug all targets, set this to -1.
430.It Dv CAM_DEBUG_LUN
431Specify a lun to debug.
432To debug all luns, set this to -1.
433.El
434.Pp
435Users may also enable debugging on the fly by using the
436.Xr camcontrol 8
437utility, if wanted options built into the kernel.
438See
439.Xr camcontrol 8
440for details.
441.Sh SEE ALSO
442.Bl -tag -width 20
443.It Sy Commands:
444.Xr camcontrol 8 ,
445.Xr camdd 8
446.It Sy Libraries:
447.Xr cam 3
448.It Sy Periph Drivers:
449.Xr ada 4 ,
450.Xr da 4 ,
451.Xr nda 4 ,
452.\" .Xr sdda 4 ,
453.Xr pass 4 ,
454.Xr sa 4
455.It Sy SIM Devices:
456.Xr aac 4 ,
457.Xr aacraid 4 ,
458.Xr ahc 4 ,
459.Xr ahci 4 ,
460.Xr ata 4 ,
461.Xr aw_mmc 4 ,
462.Xr ciss 4 ,
463.Xr hv_storvsc 4 ,
464.Xr isci 4 ,
465.Xr iscsi 4 ,
466.Xr isp 4 ,
467.\" .Xr mmcnull 4 ,
468.Xr mpr 4 ,
469.Xr mps 4 ,
470.Xr mpt 4 ,
471.Xr mrsas 4 ,
472.Xr mvs 4 ,
473.Xr nvme 4 ,
474.Xr pms 4 ,
475.Xr pvscsi 4 ,
476.Xr sdhci 4 ,
477.Xr smartpqi 4 ,
478.Xr sym 4 ,
479.Xr tws 4 ,
480.Xr umass 4 ,
481.Xr virtio_scsi 4
482.It Sy Deprecated or Poorly Supported SIM Devices:
483.Xr ahd 4 ,
484.Xr amr 4 ,
485.Xr arcmsr 4 ,
486.Xr esp 4 ,
487.\" .Xr fslsata 4 ,
488.Xr hpt27xx 4 ,
489.Xr hptiop 4 ,
490.Xr hptmv 4 ,
491.Xr hptnr 4 ,
492.\" .Xr htprr 4 ,
493.Xr iir 4
494.Xr mfi 4 ,
495.\" .Xr osc 4 ,
496.\" .Xr ps3cdrom 4 ,
497.Xr sbp 4 ,
498.Xr twa 4
499.El
500.Sh HISTORY
501The
502.Nm
503.Tn SCSI
504subsystem first appeared in
505.Fx 3.0 .
506The
507.Nm
508ATA support was added in
509.Fx 8.0 .
510.Sh AUTHORS
511.An -nosplit
512The
513.Nm
514.Tn SCSI
515subsystem was written by
516.An Justin Gibbs
517and
518.An Kenneth Merry .
519The
520.Nm
521.Tn ATA
522support was added by
523.An Alexander Motin Aq Mt mav@FreeBSD.org .
524The
525.Nm
526.Tn NVMe
527support was added by
528.An Warner Losh Aq Mt imp@FreeBSD.org .
529