Copyright © 2001, 2002, 2003, 2004 Douglas Gilbert
Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, Version 1.1 or any later version published by the Free Software Foundation; with no Invariant Sections, with no Front-Cover Texts, and with no Back-Cover Texts.
For an online copy of the license see
www.fsf.org/copyleft/fdl.html
.
2003-08-24
Revision History | ||
---|---|---|
Revision 2.1 | 2004-08-24 | dpg |
scsihosts change -> run mkinitrd, lk 2.4.21,22 | ||
Revision 2.0 | 2003-05-04 | dpg |
lk2.4.20, linuxdoc->tldp, sATA and SAS, last sector on raw devs, blockdev | ||
Revision 1.9 | 2002-11-20 | dpg |
convert to xml, lk2.4.19, spelling | ||
Revision 1.8 | 2002-05-05 | dpg |
scsihosts comma delimiter, grub+lilo | ||
Revision 1.7 | 2002-04-27 | dpg |
mkinitrd, scsi_debug, 2.4.18, more ATAPI | ||
Revision 1.6 | 2002-01-26 | dpg |
ATAPI cdrom selection | ||
Revision 1.5 | 2001-12-21 | dpg |
16 byte SCSI commands, SCSI_IOCTL_GET_PCI | ||
Revision 1.4 | 2001-08-26 | dpg |
spelling, dd_rescue, mkinitrd example, lk 2.4 changes, 1394. | ||
Revision 1.3 | 2001-08-26 | dpg |
ATAPI CDROM section, alter title, U320, iSCSI. | ||
Revision 1.2 | 2001-03-25 | dpg |
Information about scu, dt, "Alt" sequences, more notes. | ||
Revision 1.1 | 2001-01-22 | dpg |
Add osst description, _EXTRA_DEVS limitations. |
Abstract
This document describes the SCSI subsystem as the Linux kernel enters the 2.4 production series. An external view of the SCSI subsystem is the main theme. Material is included to help the system administration of the Linux SCSI subsystem. There are also brief descriptions of ioctl()s and interfaces that may be relevant to those writing applications that use this subsystem.
Table of Contents
This document describes the SCSI subsystem as the Linux kernel enters the 2.4 production series.
An external view of the SCSI subsystem is the main theme. Material is included to help the system administration of the Linux SCSI subsystem. There are also brief descriptions of ioctl()s and interfaces that may be relevant to those writing applications that use this subsystem. However internal data structures and design issues are not addressed [see reference W2]. To unclutter the presentation, compile options and system calls (including ioctl()s) have been placed in Appendix E, Compile options and System calls including ioctls. Although not strictly part of the SCSI subsystem, there is also a description of raw devices in Chapter 11, Raw devices.
For those who have no interest in the SCSI subsystem and just want to get their ATAPI cd writer going, see Section 2.4, “ATAPI cdroms”. It may also be useful to browse Chapter 2, Architectural Overview.
This document follows on from one written five years ago by Drew Eckhardt called the SCSI-HOWTO [see reference W7]. That document described the SCSI subsystem in Linux kernel 1.2 and 1.3 series. It is still available from the Linux Documentation Project [LDP, see reference W8] in its "unmaintained" section. Both documents have roughly similar structures although Drew's document has a lot of information on the adapter drivers.
This document can be found in electronic form at
www.tldp.org/HOWTO/SCSI-2.4-HOWTO
.
The home site and perhaps the most up to date version of this
document can be found at
www.torque.net/scsi/SCSI-2.4-HOWTO
(this is
the multi-page html version).
At that location this document is rendered in txt, pdf, ps, a single
(long) page of html as well as multi-page html. For example, a pdf
version is at
www.torque.net/scsi/SCSI-2.4-HOWTO.pdf
).
This document was last altered on 24th August 2004.
The SCSI subsystem has a 3 level architecture with the "upper" level being closest to the user/kernel interface while the "lower" level is closest to the hardware. The upper level drivers are commonly known by a terse two letter abbreviation (e.g. "sd" for SCSI disk driver). The names of the corresponding module drivers which, for historical reasons, sometimes differ from the built in driver names are shown in braces in the following diagram.
The upper level supports the user-kernel interface. In the case of sd and sr this is a block device interface while for st and sg this is a character device interface. Any operation using the SCSI subsystem (e.g. reading a sector from a disk) involves one driver at each of the 3 levels (e.g. sd, SCSI mid level and aic7xxx drivers).
As can be seen from the diagram, the SCSI mid level is common to all operations. The SCSI mid level defines internal interfaces and provides common services to the upper and lower level drivers. Ioctls provided by the mid level are available to the file descriptors belonging to any of the 4 upper level drivers.
The most common operation on a block device is to "mount" a file system. For a sd device typically a partition is mounted (e.g. mount -t ext2 /dev/sda6 /home). For a sr device usually the whole device is mounted (e.g. mount -t iso9660 /dev/sr0 /mnt/cdrom). The dd command can be used to read or write from block devices. In this case the block size argument ("bs") needs to be set to the block size of the device (e.g. 512 bytes for most disks) or an integral multiple of that device block size (e.g. 8192 bytes). A recent addition to the block subsystem allows a device (or partition) to be mounted more than once, at different mount points.
Sd is a member of the generic disk family, as is the hd device from the IDE subsystem. Apart from mounting sd devices, the fdisk command is available to view or modify a disk's partition table. Although the hdparm command is primarily intended for ATA disks (also known as IDE or EIDE disks), some options work on SCSI disks.
Sr is a member of the CD-ROM subsystem. Apart from mounting file systems (e.g. iso9660), audio CDs can also be read. The latter action does not involve mounting a file system but typically by invoking some ioctls. General purpose Linux commands such as dd cannot be used on audio CDs.
St is a char device for reading and writing tapes. Typically the mt command is used to perform data transfers and other control functions.
Sg is a SCSI command pass through device that uses a char device interface. General purpose Linux commands should not be used on sg devices. Applications such as SANE (for scanners), cdrecord and cdrdao (for cd writers) and cdparanoia (for reading audio CDs digitally) use sg.
Table of Contents
This section covers the various naming schemes that exist in Linux and the SCSI worlds and how they interact.
Linux has a four level hierarchical addressing scheme for SCSI devices:
SCSI adapter number [host]
channel number [bus]
id number [target]
lun [lun]
"Lun" is the common SCSI abbreviation of Logical Unit Number. The terms in brackets are the name conventions used by device pseudo file system (devfs). "Bus" is used in preference to "channel" in the description below.
The SCSI adapter number is typically an arbitrary numbering of the adapter cards on the internal IO buses (e.g. PCI, PCMCIA, ISA etc) of the computer. Such adapters are sometimes termed as HBAs (host bus adapters). SCSI adapter numbers are issued by the kernel in ascending order starting with 0.
Each HBA may control one or more SCSI buses. The various types of SCSI buses are listed in Appendix A, Common bus types (SCSI and other).
Each SCSI bus can have multiple SCSI devices connected to it. In SCSI parlance the HBA is called the "initiator" and takes up one SCSI id number (typically 7). The initiator [1] talks to targets which are commonly known as SCSI devices (e.g. disks). On SCSI parallel buses the number of ids is related to the width. 8 bit buses (sometimes called "narrow") can have 8 SCSI ids of which 1 is taken by the HBA leaving 7 for SCSI devices. Wide SCSI buses are 16 bits wide and can have a maximum of 15 SCSI devices (targets) attached. The SCSI 3 draft standard allows a large number of ids to be present on a SCSI bus.
Each SCSI device can contain multiple Logical Unit Numbers (LUNs). These are typically used by sophisticated tape and cdrom units that support multiple media.
So Linux's flavour of SCSI addressing is a four level hierarchy:
<scsi(_adapter_number), channel, id, lun>
Using the naming conventions of devfs this becomes:
<host, bus, target, lun>
A device name can be thought of as a gateway to a kernel driver that controls a device rather than the device itself. Hence there can be multiple device names some of which may offer slightly different characteristics, all mapping to the same actual device.
The device names of the various SCSI devices are found within the
/dev
directory. Traditionally in Linux, SCSI
devices have been identified by their major and minor device number
rather than their SCSI bus addresses (e.g. SCSI target id and LUN).
The device pseudo file system (devfs) moves away from the major and
minor device number scheme and for the SCSI subsystem uses device names
based on the SCSI bus addresses [discussed later in
Section 3, “Device Names in devfs” and see reference: W5].
Alternatively, there is a utility called scsidev
which addresses this issue within the scope of the Linux SCSI subsystem
and thus does not have the same system wide impact as devfs. Scsidev is
discussed later in Section 4, “Device Names in scsidev” and ref:
W6.
Eight block major numbers are reserved for SCSI disks: 8, 65, 66, 67, 68, 69, 70 and 71. Each major can accommodate 256 minor numbers which, in the case of SCSI disks, are subdivided as follows:
[b,8,0] /dev/sda [b,8,1] /dev/sda1 .... [b,8,15] /dev/sda15 [b,8,16] /dev/sdb [b,8,17] /dev/sdb1 .... [b,8,255] /dev/sdp15
The disk device names without a trailing digit refer to the whole disk
(e.g. /dev/sda
)
while those with a trailing digit refer to one of the 15 allowable
partitions
[2]
within that disk.
The remaining 7 SCSI disk block major numbers follow a similar pattern:
[b,65,0] /dev/sdq [b,65,1] /dev/sdq1 .... [b,65,159] /dev/sdz15 [b,65,160] /dev/sdaa [b,65,161] /dev/sdaa1 .... [b,65,255] /dev/sdaf15 [b,66,0] /dev/sdag [b,66,1] /dev/sdag1 .... [b,66,255] /dev/sdav15 .... [b,71,255] /dev/sddx15
So there are 128 possible disks (i.e. /dev/sda
to
/dev/sddx
) each having up
to 15 partitions. By way of contrast, the IDE subsystem allows 20 disks
(10 controllers each with 1 master and 1 slave) which can have up to 63
partitions each.
SCSI CD-ROM devices are allocated the block major number of 11. Traditionally
sr
has been the device name but scd
probably is more recognizable and is
favoured by several recent distributions. 256 SCSI CD-ROM devices are
allowed:
[b,11,0] /dev/scd0 [or /dev/sr0] [b,11,255] /dev/scd255 [or /dev/sr255]
SCSI tape devices are allocated the char major number of 9. Up to 32 tape devices are supported each of which can be accessed in one of four modes (0, 1, 2 and 3), with or without rewind. The devices are allocated as follows:
[c,9,0] /dev/st0 [tape 0, mode 0, rewind] [c,9,1] /dev/st1 [tape 1, mode 0, rewind] .... [c,9,31] /dev/st31 [tape 31, mode 0, rewind] [c,9,32] /dev/st0l [tape 0, mode 1, rewind] .... [c,9,63] /dev/st31l [tape 31, mode 1, rewind] [c,9,64] /dev/st0m [tape 0, mode 2, rewind] .... [c,9,96] /dev/st0a [tape 0, mode 3, rewind] .... [c,9,127] /dev/st31a [tape 31, mode 3, rewind] [c,9,128] /dev/nst0 [tape 0, mode 0, no rewind] .... [c,9,160] /dev/nst0l [tape 0, mode 1, no rewind] .... [c,9,192] /dev/nst0m [tape 0, mode 2, no rewind] .... [c,9,224] /dev/nst0a [tape 0, mode 3, no rewind] .... [c,9,255] /dev/nst31a [tape 31, mode 3, no rewind]
The SCSI generic (sg) devices are allocated the char major number of 21. There are 256 possible SCSI generic (sg) devices:
[c,21,0] /dev/sg0 [c,21,1] /dev/sg1 .... [c,21,255] /dev/sg255
Note that the SCSI generic device name's use of a trailing letter (e.g.
/dev/sgc
) is deprecated.
Each SCSI disk (but not each partition), each SCSI CD-ROM and each SCSI tape is mapped to an sg device. SCSI devices that don't fit into these three categories (e.g. scanners) also appear as sg devices.
Pseudo devices [see Section 1, “Pseudo drivers”] can cause devices
that are usually not considered as SCSI to appear as SCSI device names.
For example an ATAPI CD-ROM may be picked up by the ide-scsi pseudo
driver and mapped to /dev/scd0
.
The linux/Documentation/devices.txt
file supplied
within the kernel source is the definitive reference for Linux device
names and their corresponding major and minor number allocations.
The device pseudo file system can be mounted as /dev
in
which case it replaces the traditional Linux device subdirectory.
Alternatively it can be mounted elsewhere (e.g. /devfs
)
and supplement the existing device structure.
Without devfs, devices names are typically maintained in the
dev
directory
of the root partition. Hence the device names (and their associated
permissions) have file system persistence. The existence of a device name
does not necessarily imply such a device (or even its driver) is present. To
save users having to create device name entries (with the mknod
command) most Linux distributions come with thousands of device
names defined in the /dev
directory. When applications
try to open() the device name then an errno value of ENODEV indicates there
is no corresponding device (or driver) currently available.
Devfs takes a different approach in which the existence of the device name is directly related to the presence of the corresponding device (and its driver).
Assuming devfs is mounted on /dev
then SCSI devices
have primary device names that might look like this:
/dev/scsi/host0/bus0/target1/lun0/disc [whole disk] /dev/scsi/host0/bus0/target1/lun0/part6 [partition 6] /dev/scsi/host0/bus0/target1/lun0/generic [sg device for disk] /dev/scsi/host1/bus0/target2/lun0/cd [CD reader or writer] /dev/scsi/host1/bus0/target2/lun0/generic [sg device for cd] /dev/scsi/host2/bus0/target0/lun0/mt [tape mode 0 rewind] /dev/scsi/host2/bus0/target0/lun0/mtan [tape mode 3 no rewind] /dev/scsi/host2/bus0/target0/lun0/generic [sg device for tape]
The sg device on the third line corresponds to the "whole disk" on the
first line since they have the same SCSI address (i.e.
host0/bus0/target1/lun0
). If the sg driver is a module
and it has not yet been loaded (or it has been unloaded) then the
"generic" device names in the above list will not be present.
[Notice the spelling of "disc" as the devfs author favours English spelling over the American variant.] It can be seen that devfs's naming scheme closely matches the SCSI addressing discussed in Section 1, “SCSI Addressing”. It is worth noting that the IDE subsystem uses a similar devfs device naming scheme with the word "scsi" replaced with "ide". Devfs is discussed further in Chapter 12, Devfs pseudo file system.
A utility program called scsidev adds device names to
the /dev/scsi
directory that reflect the SCSI address
of each device. The first 2 letters of the name are the upper level SCSI
driver name (i.e. either sd, sr, st or sg). The number following the "h"
is the host number while the number following the "-" is meant for
host identification purposes. For PCI adapters this seems to be always
0 while for ISA adapters it is their IO address. [Perhaps this field
could be made more informative or dropped.] The numbers following
the "c", "i" and "l" are channel (bus), target id and lun values
respectively. Raw disks are shown without a trailing partition number
while partitions contained within them are shown with the partition
number following a "p".
The scsidev would typically be run as part of the
boot up sequence. It may also be useful to run it after the SCSI
configuration has changed (e.g. adding or removing lower level driver
modules, or the use of the add/remove-single-device command). After
scsidev has been run on my system which contains
2 disks, a cd reader and writer plus a scanner, then the following
names were added in the /dev/scsi
directory:
$ ls -l /dev/scsi/ # abridged total 0 brw------- 8, 0 Sep 2 11:56 sdh0-0c0i0l0 brw------- 8, 1 Sep 2 11:56 sdh0-0c0i0l0p1 ... brw------- 8, 8 Sep 2 11:56 sdh0-0c0i0l0p8 brw------- 8, 16 Sep 2 11:56 sdh0-0c0i1l0 brw------- 8, 17 Sep 2 11:56 sdh0-0c0i1l0p1 ... brw------- 8, 24 Sep 2 11:56 sdh0-0c0i1l0p8 crw------- 21, 0 Sep 2 11:56 sgh0-0c0i0l0 crw------- 21, 1 Sep 2 11:56 sgh0-0c0i1l0 crw------- 21, 2 Sep 2 11:56 sgh1-0c0i2l0 crw------- 21, 3 Sep 2 11:56 sgh1-0c0i5l0 crw------- 21, 4 Sep 2 11:56 sgh1-0c0i6l0 br-------- 11, 0 Sep 2 11:56 srh1-0c0i2l0 br-------- 11, 1 Sep 2 11:56 srh1-0c0i6l0
The mapping between the SCSI generic device names (sg) and their corresponding names when controlled by other upper level drivers (i.e. sd, sr or st) can be seen by looking for name matches when the second letter is ignored. Hence "sdh0-0c0i0l0" and "sgh0-0c0i0l0" refer to the same device. By process of elimination the "sgh1-0c0i5l0" filename is the scanner since that class of devices can only be accessed via the sg interface.
The scsidev package also includes the ability to introduce names like
/dev/scsi/scanner
by manipulating the
/etc/scsi.alias
configuration file. The package also includes
the useful rescan-scsi-bus.sh utility.
For further information about scsidev see
W6. On my system, both devfs and scsidev
co-exist happily.
[1] SCSI standards allow for multiple initiators to be present on a single bus. This is not well supported in Linux although there are patches around that improve this situation.
[2]
If 15 partitions is too limiting then the Logical Volume Manager (LVM)
might be considered. See /usr/src/linux/Documentation/LVM-HOWTO
. LVM will also allow a logical partition to span multiple
block devices.
The Linux kernel configuration is usually found in the kernel source in
the file: /usr/src/linux/.config
. It is not
recommended to edit this file directly but to use one of these configuration
options:
make config - starts a character based questions and answer session
make menuconfig - starts a terminal-oriented configuration tool (using ncurses)
make xconfig - starts a X based configuration tool
The descriptions of these selections that is displayed by the associated
help button can be found in the flat ASCII file:
/usr/src/linux/Documentation/Configure.help
Ultimately these configuration tools edit the .config
file. An option will either indicate some driver is built into the
kernel ("=y") or will be built as a module ("=m") or is not selected.
The unselected state can either be indicated by a line starting with
"#" (e.g. "# CONFIG_SCSI is not set") or by the absence of the relevant
line from the .config
file.
The 3 states of the main selection option for the SCSI subsystem (which
actually selects the SCSI mid level driver) follow. Only one of these
should appear in an actual .config
file:
CONFIG_SCSI=y CONFIG_SCSI=m # CONFIG_SCSI is not set
Some other common SCSI configuration options are:
CONFIG_BLK_DEV_SD [disk (sd) driver] CONFIG_SD_EXTRA_DEVS [extra slots for disks added later] CONFIG_BLK_DEV_SR [SCSI cdrom (sr) driver] CONFIG_BLK_DEV_SR_VENDOR [allow vendor specific cdrom commands] CONFIG_SR_EXTRA_DEVS [extra slots for cdroms added later] CONFIG_CHR_DEV_ST [tape (st) driver] CONFIG_CHR_DEV_OSST [OnSteam tape (osst) driver] CONFIG_CHR_DEV_SG [SCSI generic (sg) driver] CONFIG_DEBUG_QUEUES [for debugging multiple queues] CONFIG_SCSI_MULTI_LUN [allow probes above lun 0] CONFIG_SCSI_CONSTANTS [symbolic decode of SCSI errors] CONFIG_SCSI_LOGGING [allow logging to be runtime selected] CONFIG_SCSI_<ll_driver> [numerous lower level adapter drivers] CONFIG_SCSI_DEBUG [lower level driver for debugging] CONFIG_SCSI_PPA [older parallel port zip drives] CONFIG_SCSI_IMM [newer parallel port zip drives] CONFIG_BLK_DEV_IDESCSI [ide-scsi pseudo adapter] CONFIG_I2O_SCSI [scsi command set over i2o bus] CONFIG_SCSI_PCMCIA [for SCSI HBAs on PCMCIA bus] CONFIG_USB_STORAGE [usb "mass storage" type] CONFIG_MAGIC_SYSRQ [Alt+SysRq+S for emergency sync] [Alt+SyrRq+U for emergency remount ro]
If the root file system is on a SCSI disk then it makes sense to build into the kernel the SCSI mid level, the sd driver and the host adapter driver that the disk is connected to. In most cases it is usually safe to build the sr, st and sg drivers as modules so that they are loaded as required. If a device like a scanner is on a separate adapter then its driver may well be built as a module. In this case, that adapter driver will need to be loaded before the scanner will be recognized.
Linux distributions have many of the SCSI subsystem drivers built as modules since building all of them in would lead to a very large kernel that would exceed the capabilities of the boot loader. This leads to a "chicken and the egg" problem in which the SCSI drivers are needed to load the root file system and vice versa. The 2 phase load used by the initrd device addresses this problem (see Chapter 6, Modules and their Parameters for more details).
On a PC the motherboard's BIOS together with the SCSI BIOS provided by most SCSI host adapters takes care of the problem of loading the boot loader's image from a SCSI disk into memory and executing it. This may require some settings to be changed in the motherboard's BIOS. When more than one SCSI adapter is involved, the SCSI BIOS settings may need to change to indicate which one contains the disk with the boot image. The boot image make also come from an ATA (IDE) disk, a bootable CD-ROM or a floppy.
Both lilo and grub are commonly
used boot loaders with Linux. Their configuration files are in
/etc/lilo.conf
and /etc/grub.conf
[3]
respectively. One difference is that after changing lilo's configuration the
lilo command must be executed for the changes to take
effect (and there is no equivalent requirement for grub). See their "man"
pages for usage information. An excellent paper on lilo and the Linux bootup
sequence can be found
ftp://icaftp.epfl.ch/pub/people/almesber/booting/bootinglinux-0.ps.gz
.
For further information on grub see
www.gnu.org/software/grub
.
Some boot parameters related to the SCSI subsystem:
single [enter single user mode] <n> [enter run level <n> {0..6}] root=/dev/sda6 [*] root=/dev/scsi/host0/bus0/target0/lun0/part6 [*] root=/dev/sd/c0b0t0u0p6 [*] devfs=mount [overrides CONFIG_DEVFS_MOUNT=n] devfs=nomount [overrides CONFIG_DEVFS_MOUNT=y] init=<command> [executes <command> rather than init] quiet [reduce output to console during boot] debug [increase output to console during boot] nmi_watchdog=0 [turn off NMI watchdog on a SMP machine] max_scsi_luns=1 [limits SCSI bus scans to lun==0] scsi_allow_ghost_devices=<n>
* When devfs is in use the initial read-only mount of the root partition can be done via the old /dev/sd<a><n> notation or the new devfs notation (and two of these are shown). The joint "root=/dev/sda6 single" may be useful when disk or adapter changes have broken the kernel boot load.
The "root=" argument may also be a hex number. For example, if the root
partition is on /dev/sda3
then "root=803" is
appropriate. The last two digits are the minor device number discussed
in an earlier section.
The default argument to the "init" parameter is /sbin/init
(see man (8) init). If files such as /etc/fstab
have incorrect entries, it may be useful to drop directly
into a shell with "init=/bin/bash". However if shared libraries files
or their paths are inappropriate this may also fail. That leaves
"init=/sbin/sash" which is a statically linked shell with many useful
commands (for repairing a system) built in (see man (8) sash).
When Linux fails to boot after reporting a message like:
VFS: Cannot open root device 08:02
then the kernel expected to find a root partition on device
/dev/sda2
and did not. The numbers in the
error message are major and minor device numbers (in hex)
[see Section 2, “Device Names” for
the mapping to device names]. In such situations the "root" boot option
can be useful (also the rdev command can be used to
modify where the boot image looks for the root partition).
Lilo's configuration file /etc/lilo.conf
can take the "root=" option in two ways. The normal way is a line
like: 'root=/dev/sda2'.
In this case /dev/sda2
is converted into major
and minor numbers based on the state of the system when
the lilo command is executed. This can be
a nuisance, especially if hardware is going to be re-arranged.
The other way is a line of the form: 'append="root=/dev/sda2"'
In this case the /dev/sda2
is passed through
to the kernel the next time it is started. This is the same as
giving the "root=/dev/sda2" string at the kernel boot time prompt.
It is interpreted by the kernel at startup (once the HBAs and their
attached devices have been recognized) and thus is more flexible.
[3]
One slight wrinkle with grub is that /etc/grub.conf
is
a symbolic link to /boot/grub/grub.conf
. This can be
useful to know when /boot
is a separate partition.
There are many SCSI related modules. The mid and upper level modules are listed below:
scsi_mod.o
sd_mod.o
sr_mod.o
st.o [osst.o]
sg.o
Notice that the first 3 have "_mod" appended to their normal driver names. Lower level drivers tend to use the name (or an abbreviation) of the HBA's manufacturer (e.g. advansys) plus optionally the chip number of the major controller chip (e.g. sym53c8xx for symbios controllers based on the NCR 53c8?? family of chips).
All SCSI modules depend on the mid level. This means if the SCSI mid
level is not built into the kernel and if scsi_mod.o
has not already been loaded then a command like modprobe st
will cause the scsi_mod.o
module to be loaded. There
could well be other dependencies, for example modprobe sr_mod
will also cause the cdrom module to be loaded if it hasn't been
already. Also if the SCSI mid level is a module, then all other SCSI
subsystem drivers must be modules (this is enforced by the kernel build
configuration tools).
Modules can be loaded with the modprobe <module_name>
command which will try to load any modules that the
nominated <module_name> depends on.
Also <module_name> does not need the trailing ".o" extension which
is assumed if not given. The insmod <module_name>
command will also try
and load <module_name> but without first loading modules it depends on.
Rules for how modules can cause other modules to be loaded (with
appropriate parameters appended) are usually placed in the file
/etc/modules.conf
. [Note that in earlier Linux kernels
this file was often called /etc/conf.modules
.]
For further information about the format of this file try
man modules.conf.
Any module can have its allowable command line parameters queried with this command: modinfo -p <module_name>.
When upper level drivers are initialized and if there are no hosts active
then the mid level will attempt to load a module called "scsi_hostadapter".
An "alias" can then be used to associate "scsi_hostadapter" with the actual
name of the lower level (adapter) driver.
For example, a line like "alias scsi_hostadapter aic7xxx" in the
/etc/modules.conf
file would cause the aic7xxx module
to be loaded (if there were no lower level drivers already active).
[4]
There is a special relationship between the module parameter "scsi_hostadapter" and the initrd file system. For more information see man initrd and man mkinitrd. [5]
[4]
There is a sequencing issue here if the root file system is on the SCSI
device controlled by the lower level (adapter) driver to be loaded since
it contains the /etc/modules.conf
file. Also there
is the issue of how the boot loader obtains the initial kernel image from
a SCSI device (often from the (master) boot record). The latter is usually
taken care of by the system's or adapter card's BIOS.
[5]
An example of using mkinitrd: assume the root
partition is on a SCSI disk connected to a controller from
Adaptec that requires the aic7xxx driver. After
building a kernel with the aic7xxx driver specified as a module then
load the image into the normal place (probably in the
/boot
directory). Next make sure a line like
"alias scsi_hostadapter aic7xxx" is in the /etc/modules.conf
file. Then from the /boot
directory
execute a line like mkinitrd /boot/initrd-2.4.5.img 2.4.5
(this assumes lk 2.4.5 is being build). This should result in the
file initrd-2.4.5.img
being created. The
/etc/lilo.conf
should then have a section added
looking something like this:
image=/boot/vmlinuz-2.4.5 label=linux initrd=/boot/initrd-2.4.5.img read-only root=/dev/sda7
The following should also be selected in the kernel configuration:
CONFIG_BLK_DEV_RAM=y CONFIG_BLK_DEV_RAM_SIZE=4096 CONFIG_BLK_DEV_INITRD=y
See also Documentation/initrd.txt
.
The proc pseudo file system provides some useful information about the
SCSI subsystem. The kernel configuration option that selects "proc_fs"
is CONFIG_PROC_FS and in almost all cases it should be selected. SCSI
specific information
is found under the directory /proc/scsi
. Probably
the most commonly accessed entry is cat /proc/scsi/scsi
which lists the attached SCSI devices. See
Section 3, “proc interface” for more details.
The lower level drivers are allocated proc_fs entries of the form:
/proc/scsi/<driver_name>/<scsi_adapter_number>
where the <driver_name> is something like "aic7xxx" or "BusLogic". The <scsi_adapter_number> (also known as the host number) is the same number that was discussed in Section 1, “SCSI Addressing”. Note that one driver may control one or more hosts. What is stored in this file is lower level driver dependent (and in the case of some adapter drivers it is possible to set parameters via this file). When reporting problems to newsgroups or maintainers it is useful to include the output of this file (e.g. cat /proc/scsi/aic7xxx/0 ).
The cdrom driver provides information about attached cdrom devices
in the /proc/sys/dev/cdrom
directory. This will
include both SCSI devices (i.e. those controlled by the sr driver) and
IDE devices (i.e. those controlled by the ide-cd driver).
See Section 2.3, “sr proc interface”.
The sg driver provides information about its state and attached hosts and
devices in the /proc/scsi/sg
directory.
See Section 4.3, “sg proc interface”.
More general information on the proc pseudo file system can be found in
the kernel source file:
/usr/src/linux/Documentation/filesystems/proc.txt
.
Table of Contents
The SCSI mid level is common to all usage of the SCSI subsystem. Probably its most important role is to define internal interfaces and services that are used by all other SCSI drivers. These internal mechanisms are not discussed in this document [see ref: W2].
The primary kernel configuration parameter "CONFIG_SCSI" determines whether the mid level is built in (when "=y") or a module (when "=m"). If "CONFIG_SCSI=m" then all other SCSI subsystem drivers must also be modules.
When the mid level is built as a module then it probably never needs to be loaded explicitly because using 'modprobe' to load any other SCSI subsystem module will cause the mid level to be loaded first (if it is not already).
Some upper and lower level drivers do not (fully) load if there are no devices for that driver to control. Sometimes the report is loud as in this case for the imm driver which controls zip drives connected to a parallel port:
$ modprobe imm imm.o: init_module: No such device
lsmod will not show the "imm" module as loaded.
In other cases the result is more subtle. For example, if the sg driver
is loaded in a system with no (real or pseudo) scsi devices then the
/proc/scsi/sg
directory will not appear. [It will
be created when the first scsi device is recognized.]
SCSI drivers that are built into the kernel are checked in a pre-determined order to see if HBAs that they can control are present. The user has no control over this order which in most cases is arbitrary but in the case of some older ISA adapters is required to stop misidentification [6] .
scsi_logging=<n> where <n> is 0 to turn logging off where <n> is non-zero to turn logging on max_scsi_luns=<n> where <n> is a number between 1 and 8 (< lk 2.4.7), >= lk 2.4.7 the upper limit can be much larger scsi_allow_ghost_devices=<n> where (<n> - 1) is the maximum lu number to ghost if the the corresponding device is offline. When <n>==0 (default) then don't ghost any devices (in lk 2.4.26 and later) scsihosts=host0:hosts1::host3
The recently introduced devfs defines a "scsihosts" boot time parameter to give the user some control over this. See the devfs documentation [ref: W5] for a description. The host names given in the list to the "scsihosts" boot option are the names of lower level drivers (e.g. "scsihosts=advansys:imm::ide-scsi"). [7] [8] Devfs does not need to be present for "scsihosts" to be used. The "scsihosts" parameter, if given, is echoed during in the boot up messages. For example:
scsi: host order: advansys:imm::ide-scsi
Also if multiple HBA are present in a system then they are scanned in a fixed order (see footnote). The "scsihosts" parameter only effects how these HBAs are indexed (i.e. which SCSI adapter numbers are associated with them by the kernel). In the above example, if the "imm" driver is not found during boot up, then the scsi adapter number "1" is not allocated. If the "imm" driver is later loaded as a module, then it will adopt scsi adapter number "1". If a driver that is not named in "scsihosts" is found, then it will get the next available scsi adapter number (e.g. a built in aic7xxx driver would get scsi adapter number "2" in the above example).
A full list of kernel parameters with some explanations can be found
in the file /usr/src/linux/Documentation/kernel-parameters.txt
.
If SCSI disks are present in the system then it usually is better to build the mid level driver into the kernel. However if the SCSI subsystem is only being used periodically (e.g. to burn CD-Rs on an ATAPI CD writer) then building the mid level as a module is fine. The module load time options are the same as the driver's built in options:
scsi_logging_level=<n> where <n> is the logging level mask (0 for logging off) max_scsi_luns=<n> scsihosts=host0::host2 scsi_allow_ghost_devices=<n>
To display the SCSI devices currently attached (and recognized) by the SCSI subsystem use cat /proc/scsi/scsi.
The output looks like this:
Attached devices: Host: scsi0 Channel: 00 Id: 02 Lun: 00 Vendor: PIONEER Model: DVD-ROM DVD-303 Rev: 1.10 Type: CD-ROM ANSI SCSI revision: 02 Host: scsi1 Channel: 00 Id: 00 Lun: 00 Vendor: IBM Model: DNES-309170W Rev: SA30 Type: Direct-Access ANSI SCSI revision: 03
After the "Attached devices:" line there are 3 lines for each recognized device. The first of these lines is SCSI address information discussed in Section 1, “SCSI Addressing”. The following 2 lines of data are obtained from a INQUIRY command that was performed on the device when it was attached. See Section 4, “Generic driver (sg)” for the relationship between the ordering of these devices compared with the sg driver's ordering (which most of the time is the same).
Existing devices can be removed using echo "scsi remove-single-device <h> <b> <t> <l>" > /proc/scsi/scsi where the variables are host, bus (channel), target (scsi id) and lun. The success (or otherwise) of this command can be determined by sending a subsequent cat /proc/scsi/scsi command. The removal will fail if the device is busy (e.g. if a file system on the device is mounted).
New devices can be added using echo "scsi add-single-device <h> <b> <t> <l>" > /proc/scsi/scsi where the variables are host, bus (channel), target (scsi id) and lun. The success (or otherwise) of this command can be determined by sending a subsequent cat /proc/scsi/scsi command. [9]
The SCSI subsystem does not support hot-plugging of SCSI devices (there may also be electrical issues on the associated SCSI parallel bus). It is recommended that those who use add+remove-single-device make sure that other devices on that SCSI bus are inactive if re-plugging is going to take place.
To output a list of internal SCSI command blocks use echo "scsi dump <n>" > /proc/scsi/scsi where the numeric value of <n> doesn't matter. This is probably only of interest to people chasing down bugs within the SCSI subsystem.
To start (or stop) logging information being sent to the console/log use echo "scsi log <token> <n>" > /proc/scsi/scsi where <token> is one of: {all, none, error, timeout, scan, mlqueue, mlcomplete, llqueue, llcomplete, hlqueue, hlcomplete, ioctl} and <n> is a number between 0 and 7. The tokens "all" and "none" don't take an <n> argument. Prefix meanings:
hl upper level drivers [exception: sg uses "timeout"] ml mid level ll lower level drivers [adapter drivers often have there own flags]
The value "0" turns off logging while "7" maximizes the volume of output. Logging information will only be output if CONFIG_SCSI_LOGGING was selected in the kernel build.
Warning: "scsi log all" (and several other variants) can cause a logging
infinite loop if the log file (typically /var/log/messages
) lies on a SCSI disk. Either turn off the kernel logging
daemon or direct its output to a non SCSI device.
[6]
PCI adapters are much "safer" for initialization code than the older ISA
adapters. Hence the order of initialization of PCI adapters is unlikely
to lead to lockups. In this case the order of initialization (and thus
SCSI adapter numbers) of built in drivers may be modified by changing the
order of entries in the SCSI subsystem Makefile (
/usr/src/linux/drivers/scsi/Makefile
). Beware: some adapters
may be recognized by more than one lower level driver (e.g. those
based on NCR chipsets).
[7]
Either comma or colon can be delimiters for "scsihosts". This means that
"scsihosts=advansys,imm,,ide-scsi" is also valid. Also if a machine's
boot sequence involves an "initrd" stage (look in
/etc/grub.conf
or /etc/lilo.conf
to find out if this is the case), then the mkinitrd
command should be run after a change to the "scsihosts" boot time parameter.
This will generate a new initrd image that needs to be put in the
correct place (most probably in the /boot
directory).
[8] Using "scsihosts" can lead to a situation in which the computer's BIOS finds the boot track (and hence boot time parameters set in lilo or grub) on one disk while the kernel finds the root partition on another disk. This can be quite confusing when it is unplanned. Hence after changing (or adding) "scsihosts" in lilo or grub's configuration, it may be wise to boot the machine to see which disks are accessed.
[9] The parsing of "add-single-device" and "remove-single-device" is rather inflexible. Hence it is best to stay close to the demonstrated syntax with no extra spaces (and no tabs).
Table of Contents
The upper level drivers maintain the kernel side of the OS interface
for the logical class of devices they represent (e.g. disks). They
are also responsible for managing certain kernel and SCSI subsystem
resources such as kernel memory and SCSI command structures.
Applications in the user space access these drivers by opening a special
file (block or char) typically found in the /dev
directory tree.
Two types of SCSI devices are accessible via the sd driver:
"direct access" devices which are usually magnetic disks. [SCSI peripheral device code is 0]
"Optical memory devices" which are often called MOD disks. [SCSI peripheral device code is 7]
The sd driver is a block device which means that it is closely associated with the block subsystem. It also supports the concept of partitions. [man sd dates from 1992.]
The sd driver is capable of recognizing 128 disks when it is loaded at kernel boot time or later as a module. However, once it is loaded, it will only recognize a fixed number of additional disks. The number of additional disks that can be accommodated is set by the kernel configuration parameter CONFIG_SD_EXTRA_DEVS whose default value is 40.
CDROM and DVD drives (and WORM devices) are accessible via the sr upper
level device driver.
While "sr" is the device driver name, "sr_mod" is its module name.
The device file name is either /dev/sr<n>
or
/dev/scd<n>
.
Following is a diagram illustrating the CDROM subsystem of which sr is a part:
This diagram glosses over some of the differences between the
protocol stacks. CDROM device names are not maintained
by the uniform CDROM layer but rather by each individual protocol stack.
In the case of the SCSI subsystem, device names are maintained by the
sr driver while the IDE subsystem maintains device names with its
central "ide" driver (i.e. not by the ide-cd driver). USB and IEEE1394
cd devices names are maintained by their respective stacks. This may
partially explain why the /dev/cdrom
is often a
symbolic link to the appropriate subsystem's device name.
Two types of SCSI devices are accessible via the sr driver:
CD-ROM devices (including DVD players) [SCSI peripheral device code is 5]
"Write-once read-multiple" devices which are known as WORMs. [SCSI peripheral device code is 4]
The sr driver is capable of recognizing 256 CDROM/DVD drives when it is loaded at kernel boot time or later as a module. However, once it is loaded, it will only recognize a fixed number of additional drives. The number of additional drives that can be accommodated is set by the kernel configuration parameter CONFIG_SR_EXTRA_DEVS whose default value is 2.
People often use the dd command to read a data CDROM containing an iso9660 file system. If a count argument is not given then the dd command will read the number of 2048 byte sectors indicated by the SCSI Read Capacity command. Unfortunately this can include unwritten (or "run out") sectors at the end of the image that can cause I/O errors. Use the isosize command (see its man page) to find the true length of the iso9660 image and use that in the "count=" argument given to the dd command.
Doing a test to find out if a cdrom drive supports XA mode (mode 2) triggers firmware bugs on some drives. Consequently the check for XA mode support is turned off by default. The following module parameter is provided:
xa_test=<0|1>
to override the default. [Currently there seems to be no way to turn on XA mode testing when the sr driver is built into the kernel.]
All the following files are readable by all and produce ASCII output when read:
/proc/sys/dev/cdrom/autoclose /proc/sys/dev/cdrom/autoeject /proc/sys/dev/cdrom/check_media /proc/sys/dev/cdrom/debug /proc/sys/dev/cdrom/info /proc/sys/dev/cdrom/lock
They reflect the current state of the CDROM subsystem. This location
is part of the procfs's window through to the sysctl configuration
mechanism (see man sysctl). All but
info
are writable by the superuser. There is
a column for each CDROM and DVD player in the system in
info
(not just SCSI devices).
As an example, the auto eject feature can be turned on by the superuser with the command echo "1" > /proc/sys/dev/cdrom/autoeject. This will cause cdroms to be ejected from the drive when unmounted.
Many Linux users have no SCSI devices (or adapters) in their systems. They become a little perplexed as to why cd writer software (e.g. cdrecord and cdrdao) and cd music reading programs (e.g. cdparanoia) use the Linux SCSI subsystem. The answer is that these programs need lower level access to these devices. ATAPI (ATA Packet Interface) is essentially a SCSI command set sent over an ATA [10] transport. [The discussion in this section is also applicable to ATAPI tape drives and ATAPI floppy drives.]
Currently both cdrecord and cdparanoia interface to the SCSI generic driver (sg) and, in the case of ATAPI cd devices, use the ide-scsi pseudo device driver to access the hardware. This may change in the future as in the 2.4 series kernels a packet interface ioctl has been added to the uniform cdrom layer (see the diagram in Section 2, “CDROM driver (sr or scd)” above). [11]
The default action of the IDE subsystem in Linux is to claim all ATA devices for its built-in drivers. In the case of an ATAPI cd writer, it will be claimed by the built-in ide-cd driver. Once this has happened, the SCSI subsystem is unable to get control over an ATAPI device. The ide-scsi (pseudo lower level SCSI) driver can only register ATAPI devices in the SCSI subsystem that have not already been claimed by the IDE subsystem.
Notice the built-in qualification in the previous paragraph. If both the ide-cd and ide-scsi drivers are modules then the first one loaded will claim the ATAPI cd devices (e.g. cd/dvd readers and writers). Furthermore you can switch the controlling driver module by rmmod-ing one and modprobe-ing the other.
Probably the most flexible way to instruct the IDE core driver that you
want the cd writer at /dev/hdd
accessible to
cdrecord is to use the kernel boot option:
"hdd=ide-scsi". This will cause the ide-cd driver to bypass
/dev/hdd
(irrespective of whether ide-cd driver is
built-in or a module). As long as the ide-scsi driver is built-in or a
module then it will "capture" the cd writer
at /dev/hdd
(with the IDE core driver loading the
ide-scsi module if required).
The ide-cd driver module can be instructed to ignore certain ATA devices with the following syntax:
modprobe ide-cd ignore='hdc hdd'
In this case the ide-cd driver will ignore the devices at
/dev/hdc
and /dev/hdd
.
This effect can also be accomplished by placing a line like this:
"options ide-cd ignore=hdd" in the /etc/modules.conf
file.
A new option added in the lk 2.4 series is of the form "hdd=scsi". This option seems to have a similar function to the "hdd=ide-scsi" option discussed above. Furthermore "hdd=scsi" can only be used if both the SCSI mid-level and the ide-scsi drivers are built into the kernel (otherwise "BAD OPTION" is reported by the ide_setup function).
To find out whether an ATAPI cd device is "owned" by the SCSI subsystem, the output of cat /proc/scsi/scsi can be checked. Another technique is to observe the "drive name:" line of cat /proc/sys/dev/cdrom/info for "sr" entries. The following output is from my system:
$ cat /proc/sys/dev/cdrom/info CD-ROM information, Id: cdrom.c 3.12 2000/10/18 drive name: sr1 sr0 drive speed: 16 0 drive # of slots: 1 1 Can close tray: 1 1 Can open tray: 1 1 Can lock tray: 1 1 Can change speed: 1 1 Can select disk: 0 0 Can read multisession: 1 1 Can read MCN: 1 1 Reports media changed: 1 1 Can play audio: 1 1 Can write CD-R: 1 0 Can write CD-RW: 1 0 Can read DVD: 0 1 Can write DVD-R: 0 0 Can write DVD-RAM: 0 0
Once an ATAPI cd writer at /dev/hdd has been registered by the SCSI
subsystem, then cdroms should be mounted via the "scd" device name
and cd players should also use the "scd" device. Strangely the
hdparm command should still use the
/dev/hdd
device file (or the "echo ... > /proc/ide/hdd/settings"
method described in this section).
[12]
The tape driver interface is documented in the file
/usr/src/linux/drivers/scsi/README.st
and on the
st(4) man page (type man st). The file
README.st
also documents the different parameters and
options of the driver together with the basic mechanisms used in the driver.
The tape driver is usually accessed via the mt command
(see man mt). mtx is an associated
program for controlling tape autoloaders
(see
mtx.sourceforge.net
).
The st driver detects those SCSI devices whose peripheral device type is "Sequential-access" (code number 1) unless they appear on the driver's "reject_list". [Currently the OnStream tape drives (described in a following section) are the only entry in this reject_list.]
The st driver is capable of recognizing 32 tape drives. There are 8 device file names for each tape drive: a rewind and non-rewind variant for each of 4 modes (numbered 0 to 3). See the tape device file name examples in Section 2, “Device Names” on device names. Any number of tape drives (up to the overall limit of 32) can be added after the st driver is loaded.
ATAPI tape drives can be controlled by this driver with help from the ide-scsi pseudo adapter driver. The discussion in Section 2.4, “ATAPI cdroms” also applies for ATAPI tape drives (and ATAPI floppies).
st=xxx[,yyy] where xxx is one of the following: buffer_kbs:<n> write_threshold_kbs:<n> max_buffers:<n> max_sg_segs:<n> (The old boot parameters st=aa[,bb[,cc[,dd]]] supported but deprecated)
The default driver buffer size (buffer_kbs) is 32 (i.e. 32 KB). The default asynchronous write threshold (write_threshold_kbs) is 30 (i.e. 30 KB). The default number of buffers allocated at initialization (max_buffers) is 4. The default number of scatter/gather segments to use (max_sg_segs) is 32.
There is an auxiliary tape driver for tape drives manufactured by OnStream. It is an additional upper level driver and can co-exist with the st driver. Its driver name is "osst" (as is its module name).
The OnStream SC-x0 SCSI tape drives can not be driven by the
standard st driver, but instead need this special osst driver and
use the /dev/osst<x>
char device nodes (major 206).
[Where <x> follows the same naming scheme as st devices outlined
in Section 2, “Device Names”.]
Via usb-storage and ide-scsi, you may be able to drive the USB-x0
and DI-x0 drives as well. Note that there is also a second generation
of OnStream tape drives (ADR-x0) that supports the standard SCSI-2
commands for tapes (QIC-157) and can be driven by the standard
driver st. For more information, you may have a look at the kernel
source file /usr/src/linux/drivers/scsi/README.osst
.
More info on the OnStream driver may be found on
linux1.onstream.nl/test/
.
All types of SCSI devices are accessible via the sg driver. This means devices such as CDROM drives can be accessed both via the sr and sg drivers. Other SCSI devices such as scanners can only be accessed via the sg driver. The sg driver is capable of recognizing 256 SCSI devices. Any number of devices (up to the overall limit of 256) can be added after the sg driver is loaded.
See reference W4 for the SCSI Generic (sg) driver documentation (also found there is the sg_utils package). For SCSI standards see reference W1 and for a book on the subject of SCSI programming and pass through mechanisms see reference B3.
The sg driver in lk 2.4 is "version 3" which adds an additional interface
structure and some new ioctl()s. The most interesting new ioctl()
is SG_IO which sends a SCSI command and waits for its response.
See the Linux Documentation Project site:
www.tldp.org/HOWTO/SCSI-Generic-HOWTO/
for a full description of the sg driver.
A (possibly later) version of this document can be found at
www.torque.net/sg/p/sg_v3_ho.html
.
The abbreviation "sg" is used within the kernel to refer both to the SCSI generic driver and the scatter-gather capability offered by many modern IO devices (usually associated with DMA). The context usually makes it clear which one is being referred to. As an example, note the contorted sg ioctl() named SG_GET_SG_TABLESIZE where the second "SG" refers to scatter gather.
The public interface for sg is found in the file:
/usr/src/linux/include/scsi/sg.h
. Depending on the distribution
this may or may not contain the same information as
/usr/include/scsi/sg.h
which is controlled by the GNU library
maintainers. If these 2 files are not the same use the former header
file. Those writing applications based on sg should see its documentation
for more on this matter.
The sg driver registers all SCSI devices (with a current maximum of 256) as they are seen. Each newly registered SCSI device gets allocated the next available minor device number. At least initially this will be the same sequence that devices are displayed in mid level's cat /proc/scsi/scsi. The sg devices device mapping can be seen with cat /proc/scsi/sg/devices or cat /proc/scsi/sg/device_strs. Differences between cat /proc/scsi/scsi and sg orderings will appear when a low level driver is removed (e.g. rmmod aha1542) or when a device is removed with remove-single-device. The sg driver will leave remaining SCSI device mapping to minor device numbers unchanged. This potentially leaves a "hole" in the sg mapping. An example follows:
$ cat /proc/scsi/scsi Attached devices: Host: scsi0 Channel: 00 Id: 00 Lun: 00 Vendor: IBM Model: DNES-309170W Rev: SA30 Type: Direct-Access ANSI SCSI revision: 03 Host: scsi1 Channel: 00 Id: 02 Lun: 00 Vendor: PIONEER Model: DVD-ROM DVD-303 Rev: 1.10 Type: CD-ROM ANSI SCSI revision: 02 Host: scsi1 Channel: 00 Id: 06 Lun: 00 Vendor: YAMAHA Model: CRW4416S Rev: 1.0g Type: CD-ROM ANSI SCSI revision: 02 $ cat /proc/scsi/sg/device_strs IBM DNES-309170W SA30 PIONEER DVD-ROM DVD-303 1.10 YAMAHA CRW4416S 1.0g $ echo "scsi remove-single-device 1 0 2 0" > /proc/scsi/scsi $ cat /proc/scsi/scsi Attached devices: Host: scsi0 Channel: 00 Id: 00 Lun: 00 Vendor: IBM Model: DNES-309170W Rev: SA30 Type: Direct-Access ANSI SCSI revision: 03 Host: scsi1 Channel: 00 Id: 06 Lun: 00 Vendor: YAMAHA Model: CRW4416S Rev: 1.0g Type: CD-ROM ANSI SCSI revision: 02 $ cat /proc/scsi/sg/device_strs IBM DNES-309170W SA30 <no active device> YAMAHA CRW4416S 1.0g
Notice how the sg driver maintains the row positions of the remaining
devices in the "device_strs" output. So when the Pioneer
dvd player is removed, a hole opens up in the sg device mapping
which is not reflected in the cat /proc/scsi/scsi
output. That "hole" corresponds to the device name
/dev/sg1
.
The new sg_io_hdr interface includes a data transfer residual count field called "resid". Only some lower level adapters support this feature and those that don't always yield zero in this field. At the time of writing the advansys, aha152x and the sym53c8xx drivers support this feature.
The sg driver maintains a reserved buffer for each open file descriptor. The purpose is to guarantee applications that data transfers up to the size of the reserved buffer will not fail for lack of kernel memory. This is important for applications like cdrecord that cannot easily recover (the CDR) from a ENOMEM error.
In the absence of the boot parameter 'sg_def_reserved_size' or the sg module
parameter 'def_reserved_size', then each time a sg file descriptor is opened
the reserved buffer size is inherited from SG_DEF_RESERVED_SIZE which is
defined in include/linux/sg.h
.
The SG_DEF_RESERVED_SIZE define value can be overridden by this kernel boot option:
sg_def_reserved_size=<n>
When the sg module is loaded the SG_DEF_RESERVED_SIZE define value can be overridden by supplying this option:
def_reserved_size=<n>
All the following files are readable by all and produce ASCII output when read. The file 'def_reserved_size' is also writable by root. The ASCII output has been formatted in such a way as to be human and machine readable (and hence a compromise). Use Unix commands of the form cat device_hdrs devices to see the output of tables.
/proc/scsi/sg/debug [internal state of sg driver] /proc/scsi/sg/def_reserved_size [like boot/module load parameter] /proc/scsi/sg/devices [table of numeric device data] /proc/scsi/sg/device_hdr [column headers for sg/devices] /proc/scsi/sg/device_strs [table of strings from INQUIRY] /proc/scsi/sg/hosts [table of numeric host data] /proc/scsi/sg/host_hdr [column headers for sg/hosts] /proc/scsi/sg/host_strs [table of string ids for hosts] /proc/scsi/sg/version [sg version number and date]
All the above files are owned by root and readable by all while
def_reserved_size
is writable by root. For the
devices
and device_strs
files
the first row output corresponds to /dev/sg0
(sg minor device number 0). The second row output corresponds to
/dev/sg1
, etc.
For the hosts
and host_strs
files the first row output corresponds to host (adapter number) 0, etc.
For numeric tables a missing device or host is indicated by a row
of "-1" values. For string tables a missing device or host is indicated
by a row containing "<no active device/host>".
[10] ATA is the modern name for what was previously known as IDE and/or EIDE. Note that the subsystem that controls ATA devices in Linux is called the "IDE" subsystem for historical reasons.
[11] Other ATA devices such as tapes and floppies often use the ATAPI interface. However, the vast majority of ATA disks do not use the ATAPI interface.
[12]
In the linux 2.4 kernel series there has been an increase in problems when
the ide-scsi driver is used so that cdrecord can control
ATAPI (IDE) cd writers. The problem may be related to the aggressive manner
in which the IDE subsystem attempts to optimize the speed of data transfers
on devices it controls. Some people experiencing timeouts and machine lockups
have found that reducing the DMA setting via the hdparm
command has fixed the problem. If the cd writer is connected to
/dev/hdd
then users have reported success with one of
these two commands:
hdparm -d0 -c1 /dev/hdd hdparm -d 1 -X 34 /dev/hdd
The first one turns off DMA completely while the second one sets it in "multiword DMA mode 2". Cd writers do not need the types of speeds that modern disks utilize. Even burning at "x16" implies a sustained transfer rate of 16 times 150 KB/sec which is approximately 2.4 MB/sec, not really that fast. There has also been a report that moving a cd writer off a high speed IDE controller (Promise) and back to the motherboard's lower speed IDE controllers has fixed a random IDE bus reset problem. Another report suggests reducing (or turning off) the DMA on the IDE hard disk can also stop lockups.
Table of Contents
There are too many SCSI low level drivers to detail in this document. As an alternative to giving any superficial overview here, the reader is given suggestions of places to look for further information.
The source directory for the SCSI subsystem in the Linux kernel is a good place
to start: /usr/src/linux/drivers/scsi
. Several drivers
have information in a "readme" file: README.<driver_name>
. Others have extensive information at the top of their ".c" file
This information often includes a version number, change logs and kernel
boot time and module load
time options. Often the latter information can be found in the installation
guides of the various Linux distributions. Sometimes the driver maintainer will
have a web site containing the most recent bug fix information. Official
maintainers are listed in the /usr/src/linux/MAINTAINERS
file. If there is nothing there, look in the relevant ".c" file in the SCSI
subsystem directory. Some old drivers have no active maintainers. In such cases
posting to the linux-scsi newsgroup may help [see N1
].
For an overview of the drivers supplied with the kernel source tree,
use one of the kernel configuration programs (e.g.
cd /usr/src/linux; make menuconfig). The help
information associated with each selection can be found together in one
(large) flat file at
/usr/src/linux/Documentation/Configure.help
.
Drivers can be obtained from other places. It is unlikely that a SCSI
driver made for the lk 2.2 series (or before) will build or operate
successfully in the lk 2.4 series. [From a programmatic viewpoint
there are not a lot of things that need changing.] Drivers may even
be only available in binary form, in which case make sure that you
trust the provider and follow their instructions closely.
Lower level drivers can support either of 2 error handling strategies. The older one is considered obsolete while the newer one is often called "new_eh". The advantage of "new_eh" is that it uses a separate kernel thread per host (named "scsi_eh_<n>" where <n> is the host number) to facilitate error recovery. Both error handling strategies were also available in the lk 2.2 series in which very few adapter drivers used "new_eh". In the lk 2.4 series, more drivers are using it and the plan for the forthcoming lk 2.5 development series is to drop mid level support for the older, obsolete error strategy.
Drew Eckhardt's SCSI-HOWTO document [see reference W7 ] goes into much more detail about lower level (adapter) drivers than this document. Since that SCSI-HOWTO is 5 years old, many things have changed and more drivers have been added.
There is a lower level driver called scsi_debug
that simulates one or more "direct access" devices (i.e. disk(s)) using
the computer's memory. From lk 2.4.17 it acts as a "ram disk". While there
are many ram disk implementations available in Linux (e.g. ramfs),
scsi_debug may help to isolate a defective scsi driver in a problematic
installation. See scsi_debug.c
for further information.
SCSI can be viewed as a command set and a set of hardware buses that convey that command set. Those hardware buses can be further divided into those used exclusively for SCSI (e.g. ultra wide), those shared with other protocols (e.g. USB, IEEE 1394) and those buses not defined by the various SCSI standards. In the final category there are several interesting examples including ATAPI CD writers and PC parallel bus ZIP drives. Such devices use the SCSI command set (or something very close to it) over a foreign bus.
This section briefly outlines various pseudo lower level drivers which essentially communicate with other Linux subsystems in order to send the SCSI command set to devices controlled by those other subsystems. This raises some ownership issues that often confuse users and result in many questions to the maintainers.
IDE-SCSI. From configuration point of view, ide-scsi will grab and try to control every ATA (a.k.a. IDE) device which doesn't have a "native" driver attached (such as ide-cd, ide-tape, etc). So for example, if both ide-cd and ide-scsi are compiled into the kernel in a system which has an ATAPI cdrom, ide-cd will get to control it. If only ide-scsi is compiled in, it will get the device. There are some kernel boot time parameters to control which driver gets which device.
The preferences of the IDE subsystem can be overridden with one of these kernel boot time parameters (of which the first is most interesting for this subsystem):
hdx=ide-scsi
hdx=ide-cdrom
hdx=ide-floppy
[The term hdx is used to refer to one of the IDE/ATA devices in {hda, hdb, hdc ...}.] In the 2.4 series "hdx=scsi" was added but it is not very useful, see see Section 2.4, “ATAPI cdroms”.
When the driver is running, the device will be accessible using
the SCSI device (/dev/sda
, /dev/sr0
, etc), and not through the corresponding
/dev/hdx
device. Still, the /dev/hdx
device will be available, but only for configuration.
All the generic IDE configuration parameters (DMA on/off, 32-bit
I/O, unmasking irq's, etc) are available by using the
/dev/hdx
device, for example to enable DMA:
hdparm -d1 /dev/hdx
[13] Using cat /proc/ide/hdx/settings will show the available settings. All the generic IDE driver settings will be available there, as well as the following "ide-scsi specific" settings:
bios_cyl
bios_head
bios_sect
transform
log
The first three choose the virtual geometry that the drive will return to the sd driver, in case it's a disk drive (ZIP, etc). "transform" will configure/enable/disable the SCSI to ATAPI CDB transformation layer:
bit 0: Enable(1)/Disable(0) transformation for commands not originated from the sg driver.
bit 1: Enable/Disable transformation for commands issued using the sg driver.
"log" will log debugging information. This is useful also to debug user-space programs using the sg driver, as it will list the CDB traffic on the bus -- each issued command, along with its completion status. To enable/disable a specific settings, use something like:
echo "log:1" > /proc/ide/hdx/settings
To turn off the "using_dma" flag use:
echo "using_dma:0" > /proc/ide/hdx/settings
PPA + IMM. Iomega ZIP drives come in a variety of flavours including parallel port, SCSI, and ATAPI. The parallel port versions (both old and new) are driven by ppa and imm respectively.
The parallel port ZIP drives are actually SCSI devices which tunnel SCSI commands over the parallel port using interfaces called VPI0 (older-style) and VPI2 (newer-style). The ppa driver is the VPI0 host implementation and the imm driver is the VPI2 host implementation.
The way it works is that the HBA is a chip inside the ZIP drive, so that the host adapter and the peripheral are in the same actual case.
PPSCSI. The new, not-yet-integrated, architecture for devices that use SCSI over a parallel port cable is ppscsi. The ppscsi module provides the boiler plate code and makes it easy to write implementations for different interfaces.
Each ppscsi protocol module registers itself with the ppscsi module, passing in a list of entry points for the various things that are common to all protocol drivers.
The plan is that the ppscsi architecture will absorb both the ppa and
imm drivers and protocol modules; only vpi0 has been written so far.
See
www.torque.net/parport/ppscsi.html
.
USB.
USB classifies a group of devices as "mass storage" (e.g. disks) and
interacts with these using the SCSI command set. The module name is
"usb-storage".
See
www.one-eyed-alien.net/~mdharm/linux-usb
.
There is also the usb/microtek driver for controlling X6 USB scanners from Microtek. When configured, the SANE application uses the sg driver to send SCSI commands over USB to control this scanner.
I2O.
See kernel source file /usr/src/linux/drivers/i2o/io2_scsi.c
.
IEEE 1394. Support for IEEE 1394 devices that use the SBP-2 protocol is now available (lk 2.4.7). See the IEEE 1394 paragraph in this section for more information.
iSCSI.
An IETF draft is taking shape for iSCSI. This sends the SCSI command
set over a TCP network connection. iSCSI seems to be gaining popularity
quickly and there are several implementations for Linux taking shape.
One implementation is at
sourceforge.net/projects/intel-iscsi/
.
Use your favourite search engine to find other projects.
[13] It has been reported that in some distributions the attempt to use the hdparm command fails. In this case use the "echo ... > /proc/ide/hdx/settings" form.
A raw device can be bound to an existing block device (e.g. a disk) and be used to perform "raw" IO with that existing block device. Such "raw" IO bypasses the caching that is normally associated with block devices. Hence a raw device offers a more "direct" route to the physical device and allows an application more control over the timing of IO to that physical device. This makes raw devices suitable for complex applications like Database Management Systems that typically do their own caching.
Raw devices are character devices (major number 162). The first
minor number (i.e. 0) is reserved as a control interface and is usually
found at /dev/rawctl
. A utility called raw
(see man raw) can be used to bind a raw
device to an existing block device. These "existing block devices" may be
disks or cdroms/dvds whose underlying interface can be anything supported
by Linux (e.g. IDE/ATA or SCSI).
A sequence of commands listing the raw devices and then binding a SCSI disk partition followed by binding the whole disk looks like this on my system:
$ ls -lR /dev/raw* crw-r--r-- 1 root root 162, 0 Dec 6 06:54 /dev/rawctl /dev/raw: total 0 crw-r--r-- 1 root root 162, 1 Dec 6 06:54 raw1 crw-r--r-- 1 root root 162, 2 Dec 6 06:54 raw2 crw-r--r-- 1 root root 162, 3 Dec 6 06:54 raw3 crw-r--r-- 1 root root 162, 4 Dec 6 06:54 raw4 $ $ raw -qa $ $ raw /dev/raw/raw1 /dev/sda3 /dev/raw/raw1: bound to major 8, minor 3 $ raw /dev/raw/raw2 /dev/sda /dev/raw/raw2: bound to major 8, minor 0 $ raw -qa /dev/raw/raw1: bound to major 8, minor 3 /dev/raw/raw2: bound to major 8, minor 0
The normal array of system calls for character devices are available on raw devices. The size of the transfer for read(2) and write(2) must be an integral multiple of the physical device's block size. For a disk this will be its sector size which is normally 512 bytes. The data buffer given to read() and write() system calls must be aligned to the block size. The lseek(2) call needs to align its file read/write offset to a block boundary as well. The pread(3) call (see man pread) combines a read() and an lseek() and can be useful with raw devices (ditto with pwrite() ). Care should be taken with offsets greater than 2 GB (or perhaps 4 GB) on 32 bit architectures where the "off_t" type is 32 bits long. One solution is to use the _llseek() call (see man llseek).
Unix utilities such as recent versions of dd and lmdd (from the lmbench suite of programs) can be used to move data to and from "raw" devices as they meet the above-mentioned block alignment requirements. Recent versions of the sg_dd command in the sg_utils package can access both raw and sg devices.
Also note that if the physical device has an odd number of sectors (as shown by blockdev --getsize /dev/raw/raw*), the last sector will not be accessible using raw IO.
If a block device is being accessed via a bound raw device and also via
its normal block interface then there is no cache coherency between the
two access mechanisms. For example if /dev/sda1
was
both mounted and being accessed via a bound raw device then there could be
data inconsistencies.
The main documentation for devfs can be found at: reference
W5. The devfs name conventions for the
SCSI subsystem are outlined in Section 3, “Device Names in devfs”.
Devfs is selected by the kernel build option CONFIG_DEVFS_FS and whether
it is mounted at boot time (as /dev
) or not is
controlled by the kernel build option CONFIG_DEVFS_MOUNT. The latter option
can be overridden by the kernel boot time options "devfs=mount" or
"devfs=nomount", whichever is appropriate.
The devfs SCSI node names with their default permissions are:
disc rw------- whole disk including mbr part1 rw------- first partition {...p1} ... part15 rw------- 15th partition {...p15} cd rw-rw-rw- cd or dvd devices mt rw-rw-rw- tape mode 0 with rewind {...m0} mtl rw-rw-rw- tape mode 1 with rewind {...m1} mtm rw-rw-rw- tape mode 2 with rewind {...m2} mta rw-rw-rw- tape mode 3 with rewind {...m3} mtn rw-rw-rw- tape mode 0 with no rewind {...m0n} mtln rw-rw-rw- tape mode 1 with no rewind {...m1n} mtmn rw-rw-rw- tape mode 2 with no rewind {...m2n} mtan rw-rw-rw- tape mode 3 with no rewind {...m3n} generic rw-r-----
These node names are only present if the corresponding device (or sub-entities of the device (e.g. partitions)) and driver are present. For example if there is no sg driver present then there is no "generic" device name. The strings that appear above in braces are appended to the abridged "c0b0t0u0" notations outlined below as appropriate.
The devfs file names that are block or character special files will be called the primary device names in this description. The devfs daemon, called devfsd, introduces many symbolic links to those primary device names. This is done both for backward compatibility and convenience. These symbolic links will be called secondary device names.
The secondary device names are controlled by the devfsd configuration file
usually found in /etc/devfsd.conf
. Following is a
list of secondary device names when the default devfsd.conf file is used:
Secondary name slink to this primary device name -------------------------------------------------------------- /dev/sda /dev/scsi/host0/bus0/target2/lun0/disc /dev/sda1 /dev/scsi/host0/bus0/target2/lun0/part1 /dev/sd/c0b0t2u0 /dev/scsi/host0/bus0/target2/lun0/disc /dev/sd/c0b0t2u0p1 /dev/scsi/host0/bus0/target2/lun0/part1 /dev/sr0 /dev/scsi/host0/bus0/target4/lun0/cd /dev/sr/c0b0t4u0 /dev/scsi/host0/bus0/target4/lun0/cd /dev/st0 /dev/scsi/host1/bus0/target0/lun0/mt /dev/nst0a /dev/scsi/host1/bus0/target0/lun0/mtan /dev/st/c1b0t0u0m0 /dev/scsi/host1/bus0/target0/lun0/mt /dev/st/c1b0t0u0m3n /dev/scsi/host1/bus0/target0/lun0/mtan /dev/sg0 /dev/scsi/host0/bus0/target2/lun0/generic /dev/sg1 /dev/scsi/host0/bus0/target4/lun0/generic /dev/sg2 /dev/scsi/host1/bus0/target0/lun0/generic /dev/sg/c0b0t2u0 /dev/scsi/host0/bus0/target2/lun0/generic /dev/sg/c0b0t4u0 /dev/scsi/host0/bus0/target4/lun0/generic /dev/sg/c1b0t0u0 /dev/scsi/host1/bus0/target0/lun0/generic
Note that the more common /dev/scd0
variant for SCSI
cdroms is not supported. There are also /dev/discs
,
/dev/cdroms
and /dev/tapes
directories that contain symbolic links to all devices (i.e. not just
SCSI devices) that fall into that categorization:
Secondary name slink to this primary device ------------------------------------------------------------ /dev/discs/disc0 /dev/ide/host0/bus0/target0/lun0 * /dev/discs/disc1 /dev/scsi/host0/bus0/target2/lun0 * /dev/cdroms/cdrom0 /dev/ide/host0/bus1/target1/lun0/cd /dev/cdroms/cdrom1 /dev/scsi/host0/bus0/target4/lun0/cd /dev/tapes/tape0 /dev/scsi/host1/bus0/target0/lun0 *
Those entries marked with "*" are directories containing the primary devices. Note that IDE/ATA devices are listed before SCSI devices. These secondary device names mimic the same persistence rules as the primary device names. So when a SCSI device (?), or its lower level driver or its upper level driver are removed then so are the primary and secondary device names associated with it.
When devfs is mounted as /dev
, the old
"/dev/sda6
" type can still be used
in some contexts. This may be convenient if typing is required at the
kernel boot time prompt. For example if a user wants to change the root
partition on a "devfs" machine then any of the following examples
may be used as a kernel boot time option:
root=/dev/sda6 root=/dev/scsi/host0/bus0/target0/lun0/part6 root=/dev/sd/c0b0t0u0p6
There are many device scanning programs that expect to see the pre-devfs
device names present and it will some time before they become devfs aware.
Also some programs rely on a open of /dev/sg0
(for example) to load the
sg driver (assuming it is a module and not already loaded). This can
be arranged by an entry in /etc/devfsd.conf
file of:
LOOKUP sg.* MODLOAD
and the following in /etc/modules.devfs
:
probeall /dev/sg scsi-hosts sg alias /dev/sg* /dev/sg
The sg device permissions can be changed with this entry in the
/etc/devfsd.conf
file:
REGISTER scsi/host.*/bus.*/target.*/lun.*/generic PERMISSIONS 0.0 rw-rw-rw-
See "man devfsd" for more information.
An application can determine whether devfs is active by the presence or
otherwise of the file /dev/.devfsd
.
A feature of a /dev directory based on a persistent file system (e.g.
ext2) is the ability to associate permissions with a device file name
and keep them from one boot to the next. As noted above the default
action of devfs is to assign device file name permissions anew each time
a machine is booted. The PERMISSIONS action in the
/etc/devfsd.conf
can be used to assert permissions but
this may be considered a little awkward. The devfs document
(W5) describes a method for getting the best
of both worlds. This technique relies on the recently added feature
in lk 2.4 to mount the same file system at multiple points.
A very good overview of the various bus types touched on in this
appendix (both SCSI and others) can be found at
www.pctechguide.com/04disk2.htm
.
SCSI. The original SCSI 1 standard (ANSI specification X3.131-1986) introduced an 8 bit parallel bus that was able to do asynchronous transfers at 1.5 MegaBytes/sec and synchronous transfers up to 5 MB/sec. SCSI commands are sent at the asynchronous rate. SCSI data is transferred either at the asynchronous rate (worst case) or a negotiated synchronous rate (with 5 MB/sec being the best case).
FAST SCSI. The SCSI 2 standard raised the maximum synchronous speed to 10 MB/sec. SCSI 2 defined several parallel buses: single ended (as used by SCSI 1) and a new differential bus. The differential bus has better noise immunity and its maximum bus length is 25 metres (compared with single ended's 6 metres). Tagged queuing of commands was also added by SCSI 2.
WIDE SCSI. The SCSI 2 standard also increased the width of the bus allowing 16 and 32 bit "wide" variants. Very little use has been made of the 32 bit width so "wide" usually refers to a 16 bit wide data path. The maximum number of SCSI devices that can connect to a parallel SCSI bus is directly related to the bus width hence "wide" buses allow a maximum of 16 SCSI devices to be connected. [At least one of those devices must be the SCSI "initiator" which is usually a host adapter.]
ULTRA SCSI. Traditionally synchronous buses are clocked either on the rising or falling edge of the clock (which is normally a square wave). A recent trend has been to clock on both edges and thus double the available bandwidth. This is how ULTRA SCSI doubles the SCSI 2 "fast" speed to 20 MB/sec.
ULTRA WIDE SCSI. The same "ultra" technique applied to a (16 bit) wide SCSI parallel bus yields a bandwidth of 40 MB/sec.
ULTRA 2 WIDE SCSI. This variant introduces a new "low voltage" differential signalling (LVD) that allows the synchronous clock speed to be doubled yielding 80 MB/sec when using a (16 bit) wide bus. In this case the maximum SCSI bus length is 12 metres. To be backward compatible with ULTRA WIDE this variant can fall back to "single ended" operation. This leads to the abbreviation LVD/SE being used by adapter manufacturers. One shortcoming of this approach is that the presence of one UW device on a U2W bus will cause all other U2W devices to communicate at the slower (i.e. UW) rate. Some adapters overcome this by having separate LVD and SE physical buses on the same logical SCSI bus.
ULTRA 160 SCSI. ULTRA 160 doubles parallel SCSI bus bandwidth yet again. It uses a 16 bit wide data path, LVD signalling (see previous entry) and double transition clocking that increases the maximum synchronous bandwidth to 160 MB/sec. Additional features include cyclic redundancy codes (CRC) to improve data integrity (compared with a parity bit) and domain validation which adjusts transfer rates if the error rate is too high.
ULTRA 320 SCSI.
Shortly ULTRA 320 adapters will be available (disks with that interface
are already on the market). This is also a 16 bit wide LVD bus that can
fall back to slower speeds for compatibility with older devices. It extends
the features of Ultra 160 by doubling the clock speed. Packetized SCSI
which sends commands and status at full bus speed (rather than 5 MB/sec)
is included. Other improvements include "quick arbitration and selection",
"read and write data streaming" and CRC protection for command blocks as well
as data (Ultra 160 had CRC protection for data only). Note that adapter
cards using 64 bit PCI (or better: PCI-X) are required to stop the PCI bus
being a bottleneck at these speeds. More information can be found at
www.scsita.org
.
Recently an Ultra 320 HBA vendor claimed up to 105,000 IO operations
per second which implies per command SCSI bus overhead is less than 10
microseconds. There is a draft ULTRA 640 standard but that may be overtaken
by Serial Attached SCSI.
Serial Attached SCSI (SAS). Serial Attached SCSI (SAS) uses the same transport technology as Serial ATA (sATA) and extends it. [sATA is described below.] SAS can use external expanders to control up to 16000 devices from a single HBA. The data transfer is full duplex and 1.5 Gbps or 3.0 Gbps "phys"s can be aggregated to increase bandwidth. Cable lengths can be up to 6 meters. SAS disks are dual ported. sATA disks can be connected to a SAS expanders (but SAS disks can't be connected to a sATA HBA). SAS was demonstrated at CeBit recently but won't reach the market until 2004.
FC-AL. This stands for Fibre Channel - Arbitrated Loop and may involve dual 2 Gigabit per second single mode fibre optic links spanning 10 kilometres with throughput of up to 400 MegaBytes per second. Often associated with storage area networks (SANs). Up to 126 devices can be attached to a loop which in turn can be extended to 16 million devices in public loop mode. The transmission medium isn't necessarily fibre optic cable: copper (in the form of co-axial cable) can also be used at lower speeds and for shorter distances.
SRP/InfiniBand.
SRP (SCSI RDMA Protocol)
[
SRP_draft
] is a SCSI transport for InfiniBand
[
Infiniband_trade_association
], a high-performance
interconnect running at 10 and 30 Gbps. SRP driver source is available at
infiniband.sourceforge.net/Storage/SRP
.
IEEE 1394.
This standard also goes by the name of "Fire Wire" [trademarked
by Apple] and "iLink" [trademarked by Sony]. It is a serial bus that can run
at up to 400 Megabits/sec (IEEE 1394a). A newer standard, IEEE 1394b, ups
this to 800 Megabits/sec (with extensions to 1.6 and 3.2 Gigabits/sec) with
cable runs up to 100 metres. It has a similar but more general architecture
than USB. The IEEE 1394 standard allows for the SCSI command set to be
carried over a 1394 bus. There is a "sbp2" driver now available for
the Linux IEEE 1394 stack. This sbp2 driver is also a SCSI subsystem
lower level driver (so it is functionally similar to the ide-scsi driver).
So IEEE 1394 devices that use the SBP-2 protocol (e.g. disks, cd-rw/dvd
drives, MO drives and scanners) can be accessed via the SCSI subsystem.
See
Linux1394.sourceforge.net
for more information.
The sbp2 driver is now in lk 2.4.7 .
iSCSI. This is a new IETF standard for sending the SCSI command set over a TCP connection (or several of them). This permits SCSI devices (targets such as disks) to be network appliances, accessed locally (or potentially at a great distance) by a host machine.
NON SCSI buses. The following buses are not defined by the SCSI standards but are of interest because they either can carry the SCSI command set, are in some way related to the Linux SCSI subsystem or supply a similar functionality to SCSI products.
IDE/ATA (ATAPI).
IDE is the most used disk type on PC systems today. The acronym stands for
Integrated Drive Electronics and as the name suggests it places the bulk
of the IO "intelligence" on the disk controller card rather than spreading
it between the device (most often a disk) and a controller (HBA) as SCSI
does. IDE grew out of the ST506 and ESDI standards in the 1980s. EIDE
(extended IDE) is a related acronym. The modern standards that refer to
this bus architecture are known as ATA and can be found at
www.t13.org
. The ATA Packet Interface (ATAPI)
extends the disk oriented command set to support CDROM and tape drives.
The ATAPI command set closely resembles the SCSI command set. The
most recent ATA technology is outlined in the next paragraph.
ATA 133. The ATA standards used by IDE devices have also been marching through the adjectives (e.g. fast and ultra) and the numbers (e.g. 2, 33, 66, 100 and 133). The most recent addition is ATA 133 which supports burst rates of 133 MB/sec and up to 2 devices per bus. [PCs typically have 2 and often 4 ATA buses.] ATA 66, 100 and 133 need a special cable. ATA cables are relatively short precluding IDE devices being external to the computer. Cable lengths have previously been limited to 18 inches although 1 metre long cables have now appeared. Coincidently 133 MB/sec in also the maximum throughput of the normal PCI bus found in most PCs. The are higher speed (and wider) versions of PCI but they are relatively rare.
Serial ATA (sATA). Serial ATA uses 2 differential pairs to exchange data with a sATA disk less than 1 metre away at 1.5 Gigabits per second. One pair takes data to the disk and the other returns data from the disk. Data rates up to 150 Megabytes per second are possible (data transfer is half duplex). sATA is a point to point connection, not a bus, so ATA's master and slave strapping disappears. sATA cabling is less bulky and the form factor of its plugs and sockets are smaller than parallel ATA (and the SCSI Parallel interface). sATA devices are beginning to appear on the market. sATA-2 is a draft standard that doubles the serial data rate to 3 Gigabits per second.
USB. Universal Serial Bus (USB) has a bandwidth of between 1.5 and 12 Megabits/sec (the latter speed with USB 1.1). Up to 127 devices can be connected using a series of hubs each of which connects up to 7 devices (with a 5 metre limit). USB supplies 5 volts at 0.5 amps to power small devices. USB is "plug and play", hot pluggable and supports isochronous data transfers (required for audio and video devices that need guaranteed minimum bandwidth).
PC Parallel port. The original PC parallel port was uni-directional (towards the printer) and was capable of about 10 KB/sec. The IEEE 1284 standard in 1994 introduced 5 modes of data transfer:
Compatibility mode (forward direction)
Nibble mode (reverse direction)
Byte mode (reverse direction)
EPP mode (bi-directional)
ECP mode (bi-directional)
Enhanced Parallel Port (EPP) achieves transfer speeds of between 500 KB/sec and 2 MB/sec and is targeted at CD-ROMs, tapes and hard drives. Extended Capability Port (ECP) includes run length encoding and support for DMA. ECP is targeted at fast printers and scanners.
I2O.
"The I2O (Intelligent Input/Output) specification defines a standard
architecture for intelligent I/O that is independent of both the specific
device being controlled and the host operating system (OS)" [from www.i2osig.org
].
It defines a "split driver" model in which the OS Services Module (OSM)
sits between the host OS device interface and the I2O communications layer
while the Hardware Device Module (HDM) sits between the I2O
communications layer and the hardware. The HDM may well run on a
dedicated processor (IOP).
Table of Contents
Significant work has been done to change the single SCSI command queue used in lk 2.2 to one command queue per device. To make the SCSI subsystem more SMP friendly the granularity of the locks is much finer grained. In lk 2.2 the whole subsystem essentially used one lock.
Even though it is not part of the SCSI subsystem, the inclusion of devfs solves many SCSI device addressing problems that existed in the past. Associated with devfs but very useful even in its absence is the "scsihosts" kernel boot time (and module load time) option. This option allows users to have some control over the ordering of multiple SCSI hosts.
This appendix is difficult to maintain since features and drivers that have proven useful in lk 2.4 (and its development tree) have tended to be back ported into the higher release numbers of the lk 2.2 series.
Currently (lk 2.4.2) support for MO devices is broken. Old DOS file systems with a block size of 2048 bytes also have been reported as broken. The problem seems to arise with media that have a physical block size larger than the 1 KB logical block size used by the block subsystem. Only the sd driver has this problem (luckily not the sr driver in which 2048 byte sectors are the norm).
No sr changes reported. As a related matter, the "hdx=scsi" kernel boot option has been added. See Section 2.4, “ATAPI cdroms” for more details.
No interface changes. In lk 2.2 the maximum number of extra tape devices that could be added after boot time was limited to 3. This limitation has been removed (leaving a maximum of 32 tape devices as noted earlier).
A variant st driver called "osst" to handle early model OnStream tape drives has been added in lk 2.4 .
The main change is the addition of a new interface structure called "sg_io_hdr". The existing interface structure (called "sg_header") was found to be inflexible requiring the concatenation of raw data together with meta-data in the read() and write() commands.
sg_io_hdr {new interface structure} SG_IO {new ioctl} direct IO {present but commented out, see ALLOW_DIO} procfs output {new information in /proc/scsi/sg directory} boot/module parameters {new}
Up to 64 bytes of sense data can be obtained from the sg_io_hdr interface structure. Also a residual count associated with the data transfer is available (if the lower level driver supports it, if not the residual count will be 0).
Even though the lk 2.4 production series is meant to be "stable" there have been a significant number of changes as well as bug fixes. The following list does not include changes to the lower level (adapter) drivers. Each item of the list is prefixed by the kernel version that it was introduced. [14]
[2.4.4] added the SCSI_IOCTL_GET_PCI ioctl(),
[2.4.7] the "lun" bits (3 bits representing lun values 0 through 7 in the SCSI 1 and SCSI 2 standards) are no longer masked into the second byte of SCSI commands if the INQUIRY for that devices shows a SCSI level greater than SCSI_2,
[2.4.7] the max_scsi_luns kernel (and module scsi_mod) option previously could be 1 to 7. Now the upper value can be large. [The scan algorithms are still doing a sequential scan rather than using REPORT_LUNS.]
[2.4.7] both scsi_unregister_host() and scsi_unregister_module() now return an int (previously they were void functions). They return 0 for success, -1 for failure (typically busy),
[2.4.7] the upper level drivers now report the correct scsi device name when they are attached. [The log messages that started with "Detected ..." previously sometimes reported the wrong device (e.g. sdc rather than sdb).] Kernel boot up messages will now show SCSI devices as "Attached ...",
[2.4.7] 'max_sectors' was added to the Scsi_Host structure,
[2.4.8] some mid level logic was altered to retry commands if the sense buffer indicates that logical unit is becoming ready [ASC=4, ASQ=1],
[2.4.9] a major st update,
[2.4.9] mid level changed to retry commands if lower level (adapter) driver returned DID_RESET,
[2.4.10] original result (including SCSI status) saved when mid level issues a REQUEST SENSE so it can be restored afterwards,
[2.4.10] added BLKGETSIZE64, BLKBSZSET and BLKBSZGET ioctls to sd + sr,
[2.4.10] sg update that fixes generic_unplug_device() race + bumps access_count on opens (and decrements on releases),
[2.4.11] added MODULE_LICENSE macro in most drivers, mostly MODULE_LICENSE("GPL"),
[2.4.11] scsi_pid bumped for each command (why?),
[2.4.11] st update to bump access_count. Now all upper level drivers increment access_count on opens and decrement it on releases,
[2.4.13] scatterlist structure grows (alt_address is removed, page and offset added),
[2.4.13] don't probe luns > 7 for target <= SCSI_2 ,
[2.4.14] fine tuning (bug fixes) associated with scatterlist structure changes [it broke st ?],
[2.4.15] 16 byte SCSI commands permitted [MAX_COMMAND_SIZE changes from 12 to 16]. HBA driver must set Scsi_Host::max_cmd_len to 16 for mid level to forward 16 byte SCSI commands,
[2.4.15] BLKGETSIZE + BLKGETSIZE64 ioctl() implementations moved out of SCSI subsystem (and into block subsystem),
[2.4.15] large st update,
[2.4.15] lk 2.5.0 forks off so lk2.4.15==lk2.5.0 .
[2.4.17] add generic_unplug_device() call to scsi_wait_req(). This stops long waits in SCSI_IOCTL_SEND_COMMAND.
[2.4.17] fix device scanning bug where, in some cases, the scsi_level (i.e. SCSI standard adherence) was misplaced.
[2.4.17] major sg driver update, add mmap()-ed IO
[2.4.18] permit upper level driver "init()" functions (e.g. sd_init() ) to fail gracefully. [Add Scsi_Device::detected and scsi_unregister_module() .]
[2.4.18] Fix for clustering (SCSI commands) on MO devices.
[2.4.18] st driver update (compression algorithms).
[2.4.18] update Documentation/scsi.txt and scsi-generic.txt .
[2.4.18] Revamp scsi_debug driver .
[2.4.19] Scsi reservation and reset capability added. Reservations allow multiple machines to share the same device (via a reserve/release mechanism). Scsi reset (via sg) is needed to "break" a reservation held by a non-responding machine.
[2.4.19] Introduce BLIST_LARGELUN to handle LUNs larger than 7 despite reporting SCSI 2.
[2.4.19] Change sd and sr so RECOVERED_ERROR is not treated as a hard error. Send warning to log/console.
[2.4.19] Zero out sg's buffers before use. [Sg version upgraded from 3.1.22 to 3.1.24 but this is not reflected in sg.h (supeficial).]
[2.4.20] Support for highmem I/O added. Used by aic7xxx, 3w-xxxx, esp, megaraid, qlogicfc and sym53c8xx_2 LLDs.
[2.4.20] "blocking_open" boot time, module load time parameter added to st.
[2.4.21] Give new HBAs a new host number (higher than any previously used) unless there is a "scsihosts" match. Host numbering sequence "holes" are only re-used if there is a "scsihosts" match.
[2.4.21] stop the SCSI status RECOVERED ERROR being treated as an error by the mid level (complements a change in 2.4.19).
[2.4.21] use the TEST_UNIT_READY command (rather than START_STOP) to determine if removable media has changed (in sd driver).
[2.4.21] major work on ide-scsi driver.
[2.4.21] add aic79xx driver for Adaptec Ultra 320 controllers.
[2.4.22] Extend timeout of SEND DIAGNOSTIC command to 2 hours. This is for foreground extended self tests.
[2.4.26] Add 'scsi_allow_ghost_devices' kernel boot time and scsi_mod module option.
[2.4.27] SATA support via "libata" library introduced. SATA disks appear with SCSI subsystem names (e.g. "/dev/sdb) and respond to SCSI commands (via a command translation facility).
[14] This list has been compiled from the official 2.4 series kernels released at www.kernel.org. Distributions are free to tailor the official kernels and this may impact what is supported (or changed) in the SCSI subsystem. For example this machine reports this kernel: "2.4.18-27.8.0". So that is roughly based on the official 2.4.18 kernel which the vendor has "modded" 27 times for the "8.0" level of their distribution. As an example of the type of changes, the aic7xxx driver in the official 2.4.18 does not support Adaptec's Ultra 320 series of PCI adapters; however that vendor's version does.
Many SCSI problems are caused by cabling and (lack of, or inappropriate) termination. This often results in repeated SCSI bus resets, parity or CRC errors and sometimes reduced transfer speeds. There is a good SCSI termination tutorial at this site: www.scsita.org/aboutscsi/SCSI_Termination_Tutorial.html. There is other useful SCSI information at that site (see W9).
There is also a SCSI "faq" site (see W10) that addresses many configuration and troubleshooting issues. Although the main focus of this site is Windows (and its ASPI interface), much is relevant to SCSI in Linux and other Unix implementations.
When it looks like something has partially locked up the system, the ps command can be useful for finding out what may be causing the problem. The following options may be useful for identifying what part of the kernel may be causing the problem. This information could be forwarded to the maintainers.
ps -eo cmd,wchan ps -eo fname,tty,pid,stat,pcpu,wchan ps -eo pid,stat,pcpu,nwchan,wchan=WIDE-WCHAN-COLUMN -o args
The most interesting option for finding the location of the "hang" is
"wchan". If this is a kernel address then ps will
use /proc/ksyms
to find the nearest symbolic
location. The "nwchan" option outputs the numerical address of the "hang".
If the system is not responding to keystrokes, then <Alt+ScrollLock> in text mode should output a stack trace while <Ctrl+ScrollLock> should output a list of all processes. If the log is still working, the output will be sent there as well as appearing on the console.
If the kernel has been built with the CONFIG_MAGIC_SYSRQ, then in text mode <Alt+SysRq+H> will list available commands. Of these <Alt+SysRq+S> is useful for doing an emergency sync while <Alt+SysRq+U> will remount file systems in read only mode. After that <Alt+SysRq+B> to reboot the machine might be your next move.
scu. The SCSI Command Utility (SCU) implements various SCSI commands necessary for normal maintenance and diagnostics of SCSI peripherals. Some of its features include: formatting, scanning for (and reassigning) bad blocks, downloading new firmware, executing diagnostics and obtaining performance information. It is available on several Unix platforms (and NT), however it is only currently available in binary form. See www.bit-net.com/~rmiller/scu.html for more details.
dd. Very useful for testing the streaming performance of disks and cdroms/dvds. See man dd for more details. Here is an example for timing how long a disk takes to read 1 GB (10**9 bytes) starting from block 0:
$ time dd if=/dev/sda of=/dev/null bs=512 count=1953126
If the raw device /dev/raw/raw1
is bound to
/dev/sda
then the above line is equivalent to:
$ time dd if=/dev/raw/raw1 of=/dev/null bs=512 count=1953126
This may be slower than expected since one 512 byte sector is being read at a time. Changing the last 2 arguments to "bs=8k count=122071" should give better timings for the "raw" dd.
dt. The Data Test (DT) program is modelled on dd's syntax but dt can do a lot more than sequential copies. It is a comprehensive data test program for SCSI devices such as disks, tapes and cdrom/dvds. It is available on several Unix platforms (and NT), and its source is available (unlike its stable mate "scu" discussed earlier). See www.bit-net.com/~rmiller/dt.html for more details.
lmdd. This command is part of the lmbench suite of programs and is a variant of the dd command. It has been tailored for IO measurements and outputs timing and throughput numbers on completion. Hence the time command and a calculator are not needed.
blockdev. Fetches the sector size, the number of sectors and read ahead status of a block device (typically a disk). Can also be used to flush buffers and reread the partition table. See man blockdev.
sg_dd. This command is part of the sg_utils package (see W4) and is another variant of the dd command in which either the input and/or output file is a sg or a raw device. The block size argument ("bs") must match that of the physical device in question. The "skip" and "seek" arguments can be up to 2**31 - 1 on a 32 bit architecture allowing 1TB disks to be accessed (2G * 512). The Linux system command llseek() is used to seek with a 64 bit file read/write offset. The lmdd does not handle the > 2GB case and the dd command gets creative with multiple relative seeks. sg_dd has a "bpt" (blocks per transfer) argument that controls the number of blocks read or written in each IO transaction.
There are other programs in the sg_utils package to scan the SCSI bus (sg_scan and sg_map), to measure SCSI bus throughput (sg_rbuf and sg_turs ), show data from the SCSI inquiry command (sg_inq) and spin up (or down) media (sg_start).
dd_rescue + scsiinfo. This dd variant is designed to rescue damaged media such as SCSI (or IDE) disks and CDROMs (see W6). The scsiinfo utility for displaying and changing mode page information is also at that site.
sard.
This utility is modelled on System V Release 4's sar -d for
producing IO statistics for mounted devices and partitions. It has been
developed by Stephen Tweedie and includes the sard utility and a required
kernel patch which expands the output of /proc/partitions
. It can be found at
ftp.uk.linux.org/pub/linux/sct/fs/profiling. It collects statistics
at a relatively low level (e.g. SCSI mid level) compared to programs
like vmstat (see "man vmstat").
Table of Contents
The compile options in this appendix are those which a system administrator might conceivably want to change. Naturally the defaults are chosen so the vast majority of users will not need to modify anything. In some cases setting kernel build time options, kernel boot time parameters or module load parameters has the same effect as changing a driver compile time option.
System calls act as the interface between application programs and the kernel and its drivers. In the case of the layered driver architecture that the SCSI subsystem uses, the upper layer drivers handle most of the system calls.
The SCSI subsystem has a "bubble down" ioctl structure. First the upper level driver associated with the open file descriptor attempts to decode the ioctl. If it doesn't recognize it then the ioctl is passed down to the mid level. If the mid level doesn't recognize it then the ioctl is passed down to the lower level driver associated with the file descriptor. If the lower level driver doesn't recognize it then a EINVAL error is generated.
Some ioctls are dispatched to related subsystems.
The following header files in the kernel source are relevant to the mid level:
/usr/src/linux/include/scsi/scsi.h /usr/src/linux/include/scsi/scsi_ioctl.h
These files are meant for applications to use (other than parts in
a __KERNEL__ conditional compilation block). They may also be found in
/usr/include/scsi directory but it is best not to trust these versions as
they are maintained with the glibc library and may lag the kernel version
being used. Usually in Linux systems /usr/include/linux
can be relied upon to be a symbolic link to the kernel source's include
area (typically /usr/src/linux/include/linux
). This
symbolic link can be used to include the correct scsi_ioctl.h
using the following trick:
#include <linux/../scsi/scsi_ioctl.h>
This include file: /usr/src/linux/drivers/scsi/scsi.h
is the key internal header file for the SCSI subsystem. As such it will not
be discussed here other than to point out it has the same file name (but
it's in a different directory) as the include file mentioned at the beginning
of this section. This sometimes causes confusion.
The mid level drivers/scsi/scsi_scan.c
file
maintains an array of known SCSI devices with idiosyncrasies
. [This was known as the "black list" but that was considered
to judgmental.] The array is called "device_list". The various value are:
BLIST_NOLUN only probe lun 0
BLIST_FORCELUN force all 8 luns to be probed
BLIST_BORKEN passes through broken flag to lower level driver
BLIST_KEY sends magical MODE SENSE (pc=0x2e) to unlock device
BLIST_SINGLELUN only allow IO on one lun at a time
BLIST_NOTQ disable tagged queuing
BLIST_SPARSELUN keep going after lun not found
BLIST_MAX5LUN only probe up to lun 5
BLIST_ISDISK override INQUIRY's type with disk (direct access) type
BLIST_ISROM override INQUIRY's type with ROM
See the following files:
/usr/src/linux/include/scsi/scsi.h
Note that the SCSI status constants defined in include/scsi/scsi.h are shifted 1 bit right from the values in the SCSI standards:
scsi.h constant value SCSI 2 standard value ---------------------------------------------------- CHECK_CONDITION 0x1 0x2 CHECK_GOOD 0x2 0x4 BUSY 0x4 0x8 ....
Summary of ioctl()s follow:
SCSI_IOCTL_SEND_COMMAND This interface is deprecated - users should use the scsi generic (sg) interface instead, as this is a more flexible approach to performing generic SCSI commands on a device. The structure that we are passed should look like: struct sdata { unsigned int inlen; [i] Length of data written to device unsigned int outlen; [i] Length of data read from device unsigned char cmd[x]; [i] SCSI command (6 <= x <= 16) [o] Data read from device starts here [o] On error, sense buffer starts here unsigned char wdata[y]; [i] Data written to device starts here }; Notes: - The SCSI command length is determined by examining the 1st byte of the given command. There is no way to override this. - Data transfers are limited to PAGE_SIZE (4K on i386, 8K on alpha). - The length (x + y) must be at least OMAX_SB_LEN bytes long to accommodate the sense buffer when an error occurs. The sense buffer is truncated to OMAX_SB_LEN (16) bytes so that old code will not be surprised. - If a Unix error occurs (e.g. ENOMEM) then the user will receive a negative return and the Unix error code in 'errno'. If the SCSI command succeeds then 0 is returned. Positive numbers returned are the compacted SCSI error codes (4 bytes in one int) where the lowest byte is the SCSI status. See the drivers/scsi/scsi.h file for more information on this. SCSI_IOCTL_GET_IDLUN This ioctl takes a pointer to a "struct scsi_idlun" object as its third argument. The "struct scsi_idlun" definition is found in <scsi/scsi.h>. It gets populated with scsi host, channel, device id and lun data for the given device. Unfortunately that header file "hides" that structure behind a "#ifdef __KERNEL__" block. To use this, that structure needs to be replicated in the user's program. Something like: typedef struct my_scsi_idlun { int four_in_one; /* 4 separate bytes of info compacted into 1 int */ int host_unique_id; /* distinguishes adapter cards from same supplier */ } My_scsi_idlun; "four_in_one" is made up as follows: (scsi_device_id | (lun << 8) | (channel << 16) | (host << 24)) These 4 components are assumed (or masked) to be 1 byte each. SCSI_IOCTL_GET_BUS_NUMBER In lk 2.2 and earlier this ioctl was needed to get the host number. During lk 2.3 development the SCSI_IOCTL_GET_IDLUN ioctl was changed to include this information. Hence this ioctl is only needed for backward compatibility. SCSI_IOCTL_TAGGED_ENABLE Probably a remnant of the past when the mid level addressed such issues. Now this functionality is controlled by the lower level drivers. Best ignored. SCSI_IOCTL_TAGGED_DISABLE See comment for SCSI_IOCTL_TAGGED_ENABLE. SCSI_IOCTL_PROBE_HOST This ioctl expects its 3rd argument to be a pointer to a union that looks like this: union probe_host { unsigned int length; /* [i] max length of output ASCII string */ char str[length]; /* [o] N.B. may need '\0' appended */ }; The host associated with the device's fd either has a host dependent information string or failing that its name, output into the given structure. Note that the output starts at the beginning of given structure (overwriting the input length). N.B. A trailing '\0' may need to be put on the output string if it has been truncated by the input length. A return value of 1 indicates the host is present, 0 indicates that the host isn't present (how can that happen?) and a negative value indicates an error. SCSI_IOCTL_DOORLOCK SCSI_IOCTL_DOORUNLOCK SCSI_IOCTL_TEST_UNIT_READY Returns 0 if the unit (device) is ready, a positive number if it is not or a negative number when there is an OS error. SCSI_IOCTL_START_UNIT SCSI_IOCTL_STOP_UNIT SCSI_EMULATED_HOST {same as SG_EMULATED_HOST <new>} SCSI_IOCTL_GET_PCI Yields the PCI slot name (pci_dev::slot_name) associated with the lower level (adapter) driver that controls the current device. Up to 8 characters are output to the locations pointed to by 'arg'. If the current device is not controlled by a PCI device then errno is set to ENXIO. [This ioctl() was introduced in lk 2.4.4]
The relevant files to see:
include/linux/hdreg.h include/linux/genhd.h include/linux/fs.h
A list of ioctl()s follow:
HDIO_GETGEO_BIG HDIO_GETGEO [retrieve disk geometry] BLKGETSIZE [number of sectors in device] BLKROSET [set read only flag] BLKROGET [get read only flag] BLKRASET [set read ahead value] BLKRAGET [get read ahead value] BLKFLSBUF [instructs SCSI subsystem to flush buffers] BLKSSZGET [get device block size] BLKPG [partition table manipulation] BLKELVGET [get elevator parameters] BLKELVSET [set elevator parameters] BLKRRPART [reread the partition table] open() (all flags ignored) close() ioctl() (see list above)
See the following files:
/usr/src/linux/include/linux/cdrom.h /usr/src/linux/drivers/cdrom/cdrom.c [revision history section] /usr/src/linux/Documentation/cdrom/cdrom-standard.tex
Some of the following ioctls are described in cdrom-standard.tex :
CDROMCLOSETRAY CDROM_SET_OPTIONS CDROM_CLEAR_OPTIONS CDROM_SELECT_SPEED CDROM_SELECT_DISC CDROM_MEDIA_CHANGED CDROM_DRIVE_STATUS CDROM_CHANGER_NSLOTS CDROM_LOCKDOOR CDROM_DEBUG CDROM_GET_CAPABILITY DVD_READ_STRUCT DVD_WRITE_STRUCT DVD_AUTH CDROM_SEND_PACKET CDROM_NEXT_WRITABLE CDROM_LAST_WRITTEN
The O_NONBLOCK flag on the open() of scd devices is important. Without it the open() will wait until there is media in the device before returning.
open() O_NONBLOCK close() read() write() ioctl()
Most of the following compile options can be overridden with boot/module parameters and/or runtime configuration (i.e. ioctls).
The following parameters are defined in linux/drivers/scsi/st_options.h
ST_NOWAIT {0} ST_IN_FILE_POS {0} ST_RECOVERED_WRITE_FATAL {0} ST_DEFAULT_BLOCK {0} ST_BUFFER_BLOCKS {32} ST_WRITE_THRESHOLD_BLOCKS {30} ST_MAX_BUFFERS {4} ST_MAX_SG {16} ST_FIRST_SG {8} ST_FIRST_ORDER {5} ST_TWO_FM {0} ST_BUFFER_WRITES {1} ST_ASYNC_WRITES {1} ST_READ_AHEAD {1} ST_AUTO_LOCK {0} ST_FAST_MTEOM {0} ST_SCSI2LOGICAL {0} ST_SYSV {0}
The following parameters are defined in linux/drivers/scsi/st.c
ST_TIMEOUT {900*HZ} ST_LONG_TIMEOUT {14000*HZ}
The Linux tape interface is defined in
/usr/src/linux/include/linux/mtio.h
.
The following ioctl()s are listed in alphabetical order with a brief explanation to the right. [See st documentation (especially man 4 st) for more details.]
MTIOCTOP [execute tape commands and set drive/driver options] MTIOCGET [get the status of the drive] MTIOCPOS [get the current tape location] open() O_RDONLY, O_RDWR close() read() write() ioctl()
The following header files in the kernel source are relevant to the sg driver:
/usr/src/linux/include/scsi/sg.h
As pointed out in Section 1, “Mid level” this is best included in applications by using:
#include <linux/../scsi/sg.h>
Here are some defines from the sg.h file that the user could conceivably want to change. The current default values are shown in braces on the right:
SG_SCATTER_SZ {32768} SG_DEF_RESERVED_SIZE {SG_SCATTER_SZ} SG_DEF_FORCE_LOW_DMA {0} SG_DEF_FORCE_PACK_ID {0} SG_DEF_KEP_ORPHAN {0} SG_MAX_QUEUE {16} SG_DEFAULT_RETRIES {1} # i.e. don't retry SG_BIG_BUFF {SG_DEF_RESERVED_SIZE} SG_DEFAULT_TIMEOUT {60 seconds} SG_DEF_COMMAND_Q {0 *} SG_DEF_UNDERRUN_FLAG {0} * The per file descriptor copy of this flips to 1 (thus allowing command queuing) as soon as a write() based on the newer sg_io_hdr structure is detected.
The following ioctl()s are listed in alphabetical order with a brief explanation to the right. [See sg documentation for more details.]
SG_EMULATED_HOST [indicate if adapter is ide-scsi] SG_GET_COMMAND_Q [command queuing flag state] SG_GET_KEEP_ORPHAN [interrupted SG_IO keep orphan flag state] SG_GET_LOW_DMA ["low dma flag" (<= 16 MB on i386) state] SG_GET_NUM_WAITING [number of responses waiting to be read()] SG_GET_PACK_ID [pack_id of next to read() response (-1 if none)] SG_GET_REQUEST_TABLE [yields array of requests being processed] SG_GET_RESERVED_SIZE [current size of reserved buffer] SG_GET_SCSI_ID [a little more info than the mid level's SCSI_IOCTL_GET_IDLUN ioctl] SG_GET_SG_TABLESIZE [max entries in host's scatter gather table] SG_GET_TIMEOUT [yields timeout (unit: jiffies (10ms on i386))] SG_GET_TRANSFORM [state of ide-scsi's transform flag] SG_IO [send given SCSI command and wait for response] SG_NEXT_CMD_LEN [change command length of next command] SG_SCSI_RESET [send a SCSI bus, device or host reset] SG_SET_COMMAND_Q [set command queuing state {old=0, new=1}] SG_SET_DEBUG [set debug level {0}] SG_SET_KEEP_ORPHAN [set SG_IO's keep orphan flag {0}] SG_SET_FORCE_LOW_DMA [force DMA buffer low (<= 16 MB on i386) {0}] SG_SET_FORCE_PACK_ID [so read() can fetch by pack_id {0}] SG_SET_RESERVED_SIZE [change default buffer size {SG_DEF_RESERVED_SIZE}] SG_SET_TIMEOUT [change current timeout {60 secs} ] SG_SET_TRANSFORM [set ide-scsi's ATAPI transform flag {0}] open() [recognized oflags: O_RDONLY, O_RDWR, O_EXCL, O_NONBLOCK] close() read() write() ioctl() poll() [used when in O_NONBLOCK mode] fasync() [enables generation of SIGIO signal for read()]
WEB. The following references are found on the web. Please alert the author if any of these links become stale.
[W1] SCSI (draft) standards, resources:
www.t10.org
[W2] Eric Youngdale is the chief architect of the Linux SCSI subsystem:
www.andante.org/scsi.html
[W4] The author's scsi generic (sg) site is:
www.torque.net/sg
.
The Linux Documentation Project's site includes the
www.tldp.org/HOWTO/SCSI-Generic-HOWTO/
.
A (possibly later) version of that document can be found at
www.torque.net/sg/p/sg_v3_ho
.
The sg_utils and sg3_utils packages, as tarballs and as binary and source
rpms can also be found on this page. These packages and others available
for the sg driver are discussed at
www.torque.net/sg/u_index.html
.
[W5] Richard Gooch's devfs site:
www.atnf.csiro.au/~rgooch/linux/docs/devfs.html
[W6] Kurt Garloff's site (including the scsidev
and the scsiinfo utilities):
www.garloff.de/kurt/linux/
. Kurt also has
the damaged media rescue program dd_rescue at this site:
www.garloff.de/kurt/linux/ddrescue
[W7] Drew Eckhardt's SCSI-HOWTO from 1996 (in ASCII):
metalab.unc.edu/pub/Linux/docs/HOWTO/unmaintained/SCSI-HOWTO
[W8] Linux Documentation Project (LDP):
tldp.org
[W9] SCSI Trade Association site has a lot of useful information:
www.scsita.org
[W10] SCSI FAQ site - useful source of information and links:
www.scsifaq.org
NEWSGROUPS.
The following entries are actually reflectors rather than newsgroups.
Various web locations archive their contents (e.g.
marc.theaimsgroup.com
).
[N1] Linux SCSI reflector: < linux-scsi@vger.kernel.org >
.
This is a relatively low volume (circa 200 postings per month) Linux
SCSI specific group that many of the SCSI subsystem maintainers
monitor.
[N2] Linux kernel reflector: < linux-kernel@vger.kernel.org >
.
This is a relatively high volume (circa 5000 postings per month) group
for all aspects of the Linux kernel. The Linux SCSI reflector should
be tried first.
BOOKS. Here are some books that the author found useful.
[B1] "Linux Device Drivers" Second edition by Alessandro Rubini
and Jonathan Corbet [O'Reilly 2001 ISBN 0-596-00008-1]
This is a solid text on Linux device drivers including some information
on the SCSI subsystem. It covers the block subsystem well and has
many char device driver examples. It has been updated for the Linux
2.4 series kernels and also includes information on the Linux 2.2 and 2.0
series. This book is highly recommended.
The authors
and the publisher have unselfishly made this book available under the GNU
Free Documentation License (version 1.1). It can be found in html at
www.xml.com/ldd/chapter/book
.
[B2] "Running Linux" 3rd edition by M. Welsh, M. K. Dalheimer & L. Kaufman [O'Reilly 1999 ISBN 1-56592-469-X] This is a classic Linux tome which includes some SCSI configuration info.
[B3] "The Programmer's Guide to SCSI" by Brian Sawert [Addison Wesley 1998 ISBN 0-201-18538-5] This book covers many SCSI topics, including the pass through mechanisms of Linux (sg) and ASPI/ASPI32 as used by Windows.
CREDITS. The author is grateful for the following contributions:
Kai Mäkisara (st) <Kai.Makisara at metla
dot fi>
Jens Axboe (sr) <axboe at suse dot de>
Richard Gooch (devfs) <rgooch at atnf dot csiro
dot au>
Tim Waugh (ppa, imm, ppscsi + docbook)
<twaugh at redhat dot com>
Gadi Oxman (ide-scsi)
<gadio at netvision dot net dot il>
CORRECTIONS and SUGGESTIONS.
Please send any corrections or suggestions to the author at
<dgilbert at interlog dot com>
or <dougg at torque
dot net>
.