Merge rsync://rsync.kernel.org/pub/scm/linux/kernel/git/torvalds/linux-2.6

Conflicts:

	drivers/usb/input/hid.h
This commit is contained in:
Dmitry Torokhov 2006-12-08 01:07:56 -05:00
commit bef986502f
4033 changed files with 157167 additions and 79875 deletions

1
.gitignore vendored
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@ -20,6 +20,7 @@
# Top-level generic files
#
tags
TAGS
vmlinux*
System.map
Module.symvers

11
CREDITS
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@ -45,7 +45,7 @@ S: Longford, Ireland
S: Sydney, Australia
N: Tigran A. Aivazian
E: tigran@veritas.com
E: tigran@aivazian.fsnet.co.uk
W: http://www.moses.uklinux.net/patches
D: BFS filesystem
D: Intel IA32 CPU microcode update support
@ -2598,6 +2598,9 @@ S: Ucitelska 1576
S: Prague 8
S: 182 00 Czech Republic
N: Rick Payne
D: RFC2385 Support for TCP
N: Barak A. Pearlmutter
E: bap@cs.unm.edu
W: http://www.cs.unm.edu/~bap/
@ -3511,14 +3514,12 @@ D: The Linux Support Team Erlangen
N: David Weinehall
E: tao@acc.umu.se
P: 1024D/DC47CA16 7ACE 0FB0 7A74 F994 9B36 E1D1 D14E 8526 DC47 CA16
W: http://www.acc.umu.se/~tao/
W: http://www.acc.umu.se/~mcalinux/
D: v2.0 kernel maintainer
D: Fixes for the NE/2-driver
D: Miscellaneous MCA-support
D: Cleanup of the Config-files
S: Axtorpsvagen 40:20
S: S-903 37 UMEA
S: Sweden
N: Matt Welsh
E: mdw@metalab.unc.edu

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@ -104,8 +104,6 @@ firmware_class/
- request_firmware() hotplug interface info.
floppy.txt
- notes and driver options for the floppy disk driver.
ftape.txt
- notes about the floppy tape device driver.
hayes-esp.txt
- info on using the Hayes ESP serial driver.
highuid.txt

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@ -201,7 +201,7 @@ udev
----
udev is a userspace application for populating /dev dynamically with
only entries for devices actually present. udev replaces the basic
functionality of devfs, while allowing persistant device naming for
functionality of devfs, while allowing persistent device naming for
devices.
FUSE

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@ -77,7 +77,7 @@ To get this part of the dma_ API, you must #include <linux/dmapool.h>
Many drivers need lots of small dma-coherent memory regions for DMA
descriptors or I/O buffers. Rather than allocating in units of a page
or more using dma_alloc_coherent(), you can use DMA pools. These work
much like a kmem_cache_t, except that they use the dma-coherent allocator
much like a struct kmem_cache, except that they use the dma-coherent allocator
not __get_free_pages(). Also, they understand common hardware constraints
for alignment, like queue heads needing to be aligned on N byte boundaries.
@ -94,7 +94,7 @@ The pool create() routines initialize a pool of dma-coherent buffers
for use with a given device. It must be called in a context which
can sleep.
The "name" is for diagnostics (like a kmem_cache_t name); dev and size
The "name" is for diagnostics (like a struct kmem_cache name); dev and size
are like what you'd pass to dma_alloc_coherent(). The device's hardware
alignment requirement for this type of data is "align" (which is expressed
in bytes, and must be a power of two). If your device has no boundary
@ -431,10 +431,10 @@ be identical to those passed in (and returned by
dma_alloc_noncoherent()).
int
dma_is_consistent(dma_addr_t dma_handle)
dma_is_consistent(struct device *dev, dma_addr_t dma_handle)
returns true if the memory pointed to by the dma_handle is actually
consistent.
returns true if the device dev is performing consistent DMA on the memory
area pointed to by the dma_handle.
int
dma_get_cache_alignment(void)
@ -459,7 +459,7 @@ anything like this. You must also be extra careful about accessing
memory you intend to sync partially.
void
dma_cache_sync(void *vaddr, size_t size,
dma_cache_sync(struct device *dev, void *vaddr, size_t size,
enum dma_data_direction direction)
Do a partial sync of memory that was allocated by
@ -489,7 +489,7 @@ size is the size of the area (must be multiples of PAGE_SIZE).
flags can be or'd together and are
DMA_MEMORY_MAP - request that the memory returned from
dma_alloc_coherent() be directly writeable.
dma_alloc_coherent() be directly writable.
DMA_MEMORY_IO - request that the memory returned from
dma_alloc_coherent() be addressable using read/write/memcpy_toio etc.

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@ -110,7 +110,7 @@ lock.
Once the DMA transfer is finished (or timed out) you should disable
the channel again. You should also check get_dma_residue() to make
sure that all data has been transfered.
sure that all data has been transferred.
Example:

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@ -191,8 +191,12 @@ quiet_cmd_fig2png = FIG2PNG $@
# Help targets as used by the top-level makefile
dochelp:
@echo ' Linux kernel internal documentation in different formats:'
@echo ' xmldocs (XML DocBook), psdocs (Postscript), pdfdocs (PDF)'
@echo ' htmldocs (HTML), mandocs (man pages, use installmandocs to install)'
@echo ' htmldocs - HTML'
@echo ' installmandocs - install man pages generated by mandocs'
@echo ' mandocs - man pages'
@echo ' pdfdocs - PDF'
@echo ' psdocs - Postscript'
@echo ' xmldocs - XML DocBook'
###
# Temporary files left by various tools

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@ -418,9 +418,35 @@ X!Edrivers/pnp/system.c
!Idrivers/parport/daisy.c
</chapter>
<chapter id="viddev">
<title>Video4Linux</title>
!Edrivers/media/video/videodev.c
<chapter id="message_devices">
<title>Message-based devices</title>
<sect1><title>Fusion message devices</title>
!Edrivers/message/fusion/mptbase.c
!Idrivers/message/fusion/mptbase.c
!Edrivers/message/fusion/mptscsih.c
!Idrivers/message/fusion/mptscsih.c
!Idrivers/message/fusion/mptctl.c
!Idrivers/message/fusion/mptspi.c
!Idrivers/message/fusion/mptfc.c
!Idrivers/message/fusion/mptlan.c
</sect1>
<sect1><title>I2O message devices</title>
!Iinclude/linux/i2o.h
!Idrivers/message/i2o/core.h
!Edrivers/message/i2o/iop.c
!Idrivers/message/i2o/iop.c
!Idrivers/message/i2o/config-osm.c
!Edrivers/message/i2o/exec-osm.c
!Idrivers/message/i2o/exec-osm.c
!Idrivers/message/i2o/bus-osm.c
!Edrivers/message/i2o/device.c
!Idrivers/message/i2o/device.c
!Idrivers/message/i2o/driver.c
!Idrivers/message/i2o/pci.c
!Idrivers/message/i2o/i2o_block.c
!Idrivers/message/i2o/i2o_scsi.c
!Idrivers/message/i2o/i2o_proc.c
</sect1>
</chapter>
<chapter id="snddev">

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@ -345,7 +345,6 @@ static inline void skel_delete (struct usb_skel *dev)
usb_buffer_free (dev->udev, dev->bulk_out_size,
dev->bulk_out_buffer,
dev->write_urb->transfer_dma);
if (dev->write_urb != NULL)
usb_free_urb (dev->write_urb);
kfree (dev);
}

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@ -365,6 +365,7 @@ You can change this at module load time (for a module) with:
regshifts=<shift1>,<shift2>,...
slave_addrs=<addr1>,<addr2>,...
force_kipmid=<enable1>,<enable2>,...
unload_when_empty=[0|1]
Each of these except si_trydefaults is a list, the first item for the
first interface, second item for the second interface, etc.
@ -416,6 +417,11 @@ by the driver, but systems with broken interrupts might need an enable,
or users that don't want the daemon (don't need the performance, don't
want the CPU hit) can disable it.
If unload_when_empty is set to 1, the driver will be unloaded if it
doesn't find any interfaces or all the interfaces fail to work. The
default is one. Setting to 0 is useful with the hotmod, but is
obviously only useful for modules.
When compiled into the kernel, the parameters can be specified on the
kernel command line as:
@ -441,6 +447,25 @@ have high-res timers enabled in the kernel and you don't have
interrupts enabled, the driver will run VERY slowly. Don't blame me,
these interfaces suck.
The driver supports a hot add and remove of interfaces. This way,
interfaces can be added or removed after the kernel is up and running.
This is done using /sys/modules/ipmi_si/hotmod, which is a write-only
parameter. You write a string to this interface. The string has the
format:
<op1>[:op2[:op3...]]
The "op"s are:
add|remove,kcs|bt|smic,mem|i/o,<address>[,<opt1>[,<opt2>[,...]]]
You can specify more than one interface on the line. The "opt"s are:
rsp=<regspacing>
rsi=<regsize>
rsh=<regshift>
irq=<irq>
ipmb=<ipmb slave addr>
and these have the same meanings as discussed above. Note that you
can also use this on the kernel command line for a more compact format
for specifying an interface. Note that when removing an interface,
only the first three parameters (si type, address type, and address)
are used for the comparison. Any options are ignored for removing.
The SMBus Driver
----------------
@ -502,7 +527,10 @@ used to control it:
modprobe ipmi_watchdog timeout=<t> pretimeout=<t> action=<action type>
preaction=<preaction type> preop=<preop type> start_now=x
nowayout=x
nowayout=x ifnum_to_use=n
ifnum_to_use specifies which interface the watchdog timer should use.
The default is -1, which means to pick the first one registered.
The timeout is the number of seconds to the action, and the pretimeout
is the amount of seconds before the reset that the pre-timeout panic will
@ -624,5 +652,9 @@ command line. The parameter is also available via the proc filesystem
in /proc/sys/dev/ipmi/poweroff_powercycle. Note that if the system
does not support power cycling, it will always do the power off.
The "ifnum_to_use" parameter specifies which interface the poweroff
code should use. The default is -1, which means to pick the first one
registered.
Note that if you have ACPI enabled, the system will prefer using ACPI to
power off.

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@ -219,7 +219,7 @@ into the field vector of each element contained in a second argument.
Note that the pre-assigned IOAPIC dev->irq is valid only if the device
operates in PIN-IRQ assertion mode. In MSI-X mode, any attempt at
using dev->irq by the device driver to request for interrupt service
may result unpredictabe behavior.
may result in unpredictable behavior.
For each MSI-X vector granted, a device driver is responsible for calling
other functions like request_irq(), enable_irq(), etc. to enable

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@ -96,9 +96,9 @@ a) TASKSTATS_TYPE_AGGR_PID/TGID : attribute containing no payload but indicates
a pid/tgid will be followed by some stats.
b) TASKSTATS_TYPE_PID/TGID: attribute whose payload is the pid/tgid whose stats
is being returned.
are being returned.
c) TASKSTATS_TYPE_STATS: attribute with a struct taskstsats as payload. The
c) TASKSTATS_TYPE_STATS: attribute with a struct taskstats as payload. The
same structure is used for both per-pid and per-tgid stats.
3. New message sent by kernel whenever a task exits. The payload consists of a
@ -122,12 +122,12 @@ of atomicity).
However, maintaining per-process, in addition to per-task stats, within the
kernel has space and time overheads. To address this, the taskstats code
accumalates each exiting task's statistics into a process-wide data structure.
When the last task of a process exits, the process level data accumalated also
accumulates each exiting task's statistics into a process-wide data structure.
When the last task of a process exits, the process level data accumulated also
gets sent to userspace (along with the per-task data).
When a user queries to get per-tgid data, the sum of all other live threads in
the group is added up and added to the accumalated total for previously exited
the group is added up and added to the accumulated total for previously exited
threads of the same thread group.
Extending taskstats

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@ -24,8 +24,10 @@ very similar behavior to the deadline IO scheduler.
Selecting IO schedulers
-----------------------
To choose IO schedulers at boot time, use the argument 'elevator=deadline'.
'noop' and 'as' (the default) are also available. IO schedulers are assigned
globally at boot time only presently.
'noop', 'as' and 'cfq' (the default) are also available. IO schedulers are
assigned globally at boot time only presently. It's also possible to change
the IO scheduler for a determined device on the fly, as described in
Documentation/block/switching-sched.txt.
Anticipatory IO scheduler Policies

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@ -183,7 +183,7 @@ it, the pci dma mapping routines and associated data structures have now been
modified to accomplish a direct page -> bus translation, without requiring
a virtual address mapping (unlike the earlier scheme of virtual address
-> bus translation). So this works uniformly for high-memory pages (which
do not have a correponding kernel virtual address space mapping) and
do not have a corresponding kernel virtual address space mapping) and
low-memory pages.
Note: Please refer to DMA-mapping.txt for a discussion on PCI high mem DMA
@ -391,7 +391,7 @@ forced such requests to be broken up into small chunks before being passed
on to the generic block layer, only to be merged by the i/o scheduler
when the underlying device was capable of handling the i/o in one shot.
Also, using the buffer head as an i/o structure for i/os that didn't originate
from the buffer cache unecessarily added to the weight of the descriptors
from the buffer cache unnecessarily added to the weight of the descriptors
which were generated for each such chunk.
The following were some of the goals and expectations considered in the
@ -403,14 +403,14 @@ i. Should be appropriate as a descriptor for both raw and buffered i/o -
for raw i/o.
ii. Ability to represent high-memory buffers (which do not have a virtual
address mapping in kernel address space).
iii.Ability to represent large i/os w/o unecessarily breaking them up (i.e
iii.Ability to represent large i/os w/o unnecessarily breaking them up (i.e
greater than PAGE_SIZE chunks in one shot)
iv. At the same time, ability to retain independent identity of i/os from
different sources or i/o units requiring individual completion (e.g. for
latency reasons)
v. Ability to represent an i/o involving multiple physical memory segments
(including non-page aligned page fragments, as specified via readv/writev)
without unecessarily breaking it up, if the underlying device is capable of
without unnecessarily breaking it up, if the underlying device is capable of
handling it.
vi. Preferably should be based on a memory descriptor structure that can be
passed around different types of subsystems or layers, maybe even
@ -1013,7 +1013,7 @@ Characteristics:
i. Binary tree
AS and deadline i/o schedulers use red black binary trees for disk position
sorting and searching, and a fifo linked list for time-based searching. This
gives good scalability and good availablility of information. Requests are
gives good scalability and good availability of information. Requests are
almost always dispatched in disk sort order, so a cache is kept of the next
request in sort order to prevent binary tree lookups.

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@ -1,7 +1,7 @@
The cpufreq-nforce2 driver changes the FSB on nVidia nForce2 plattforms.
The cpufreq-nforce2 driver changes the FSB on nVidia nForce2 platforms.
This works better than on other plattforms, because the FSB of the CPU
This works better than on other platforms, because the FSB of the CPU
can be controlled independently from the PCI/AGP clock.
The module has two options:

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@ -55,7 +55,7 @@ additional_cpus=n (*) Use this to limit hotpluggable cpus. This option sets
ia64 and x86_64 use the number of disabled local apics in ACPI tables MADT
to determine the number of potentially hot-pluggable cpus. The implementation
should only rely on this to count the # of cpus, but *MUST* not rely on the
apicid values in those tables for disabled apics. In the event BIOS doesnt
apicid values in those tables for disabled apics. In the event BIOS doesn't
mark such hot-pluggable cpus as disabled entries, one could use this
parameter "additional_cpus=x" to represent those cpus in the cpu_possible_map.

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@ -3,7 +3,7 @@
Maintained by Torben Mathiasen <device@lanana.org>
Last revised: 15 May 2006
Last revised: 29 November 2006
This list is the Linux Device List, the official registry of allocated
device numbers and /dev directory nodes for the Linux operating
@ -92,8 +92,9 @@ Your cooperation is appreciated.
7 = /dev/full Returns ENOSPC on write
8 = /dev/random Nondeterministic random number gen.
9 = /dev/urandom Faster, less secure random number gen.
10 = /dev/aio Asyncronous I/O notification interface
10 = /dev/aio Asynchronous I/O notification interface
11 = /dev/kmsg Writes to this come out as printk's
1 block RAM disk
0 = /dev/ram0 First RAM disk
1 = /dev/ram1 Second RAM disk
@ -506,6 +507,7 @@ Your cooperation is appreciated.
33 = /dev/patmgr1 Sequencer patch manager
34 = /dev/midi02 Third MIDI port
50 = /dev/midi03 Fourth MIDI port
14 block BIOS harddrive callback support {2.6}
0 = /dev/dos_hda First BIOS harddrive whole disk
64 = /dev/dos_hdb Second BIOS harddrive whole disk
@ -527,6 +529,7 @@ Your cooperation is appreciated.
16 char Non-SCSI scanners
0 = /dev/gs4500 Genius 4500 handheld scanner
16 block GoldStar CD-ROM
0 = /dev/gscd GoldStar CD-ROM
@ -548,6 +551,7 @@ Your cooperation is appreciated.
0 = /dev/ttyC0 First Cyclades port
...
31 = /dev/ttyC31 32nd Cyclades port
19 block "Double" compressed disk
0 = /dev/double0 First compressed disk
...
@ -563,6 +567,7 @@ Your cooperation is appreciated.
0 = /dev/cub0 Callout device for ttyC0
...
31 = /dev/cub31 Callout device for ttyC31
20 block Hitachi CD-ROM (under development)
0 = /dev/hitcd Hitachi CD-ROM
@ -639,6 +644,7 @@ Your cooperation is appreciated.
26 char Quanta WinVision frame grabber {2.6}
0 = /dev/wvisfgrab Quanta WinVision frame grabber
26 block Second Matsushita (Panasonic/SoundBlaster) CD-ROM
0 = /dev/sbpcd4 Panasonic CD-ROM controller 1 unit 0
1 = /dev/sbpcd5 Panasonic CD-ROM controller 1 unit 1
@ -670,6 +676,7 @@ Your cooperation is appreciated.
37 = /dev/nrawqft1 Unit 1, no rewind-on-close, no file marks
38 = /dev/nrawqft2 Unit 2, no rewind-on-close, no file marks
39 = /dev/nrawqft3 Unit 3, no rewind-on-close, no file marks
27 block Third Matsushita (Panasonic/SoundBlaster) CD-ROM
0 = /dev/sbpcd8 Panasonic CD-ROM controller 2 unit 0
1 = /dev/sbpcd9 Panasonic CD-ROM controller 2 unit 1
@ -681,6 +688,7 @@ Your cooperation is appreciated.
1 = /dev/staliomem1 Second Stallion card I/O memory
2 = /dev/staliomem2 Third Stallion card I/O memory
3 = /dev/staliomem3 Fourth Stallion card I/O memory
28 char Atari SLM ACSI laser printer (68k/Atari)
0 = /dev/slm0 First SLM laser printer
1 = /dev/slm1 Second SLM laser printer
@ -690,6 +698,7 @@ Your cooperation is appreciated.
1 = /dev/sbpcd13 Panasonic CD-ROM controller 3 unit 1
2 = /dev/sbpcd14 Panasonic CD-ROM controller 3 unit 2
3 = /dev/sbpcd15 Panasonic CD-ROM controller 3 unit 3
28 block ACSI disk (68k/Atari)
0 = /dev/ada First ACSI disk whole disk
16 = /dev/adb Second ACSI disk whole disk
@ -750,6 +759,7 @@ Your cooperation is appreciated.
31 char MPU-401 MIDI
0 = /dev/mpu401data MPU-401 data port
1 = /dev/mpu401stat MPU-401 status port
31 block ROM/flash memory card
0 = /dev/rom0 First ROM card (rw)
...
@ -818,6 +828,7 @@ Your cooperation is appreciated.
129 = /dev/smpte1 Second MIDI port, SMPTE timed
130 = /dev/smpte2 Third MIDI port, SMPTE timed
131 = /dev/smpte3 Fourth MIDI port, SMPTE timed
35 block Slow memory ramdisk
0 = /dev/slram Slow memory ramdisk
@ -828,6 +839,7 @@ Your cooperation is appreciated.
16 = /dev/tap0 First Ethertap device
...
31 = /dev/tap15 16th Ethertap device
36 block MCA ESDI hard disk
0 = /dev/eda First ESDI disk whole disk
64 = /dev/edb Second ESDI disk whole disk
@ -882,6 +894,7 @@ Your cooperation is appreciated.
40 char Matrox Meteor frame grabber {2.6}
0 = /dev/mmetfgrab Matrox Meteor frame grabber
40 block Syquest EZ135 parallel port removable drive
0 = /dev/eza Parallel EZ135 drive, whole disk
@ -893,6 +906,7 @@ Your cooperation is appreciated.
41 char Yet Another Micro Monitor
0 = /dev/yamm Yet Another Micro Monitor
41 block MicroSolutions BackPack parallel port CD-ROM
0 = /dev/bpcd BackPack CD-ROM
@ -901,6 +915,7 @@ Your cooperation is appreciated.
the parallel port ATAPI CD-ROM driver at major number 46.
42 char Demo/sample use
42 block Demo/sample use
This number is intended for use in sample code, as
@ -918,6 +933,7 @@ Your cooperation is appreciated.
0 = /dev/ttyI0 First virtual modem
...
63 = /dev/ttyI63 64th virtual modem
43 block Network block devices
0 = /dev/nb0 First network block device
1 = /dev/nb1 Second network block device
@ -934,6 +950,7 @@ Your cooperation is appreciated.
0 = /dev/cui0 Callout device for ttyI0
...
63 = /dev/cui63 Callout device for ttyI63
44 block Flash Translation Layer (FTL) filesystems
0 = /dev/ftla FTL on first Memory Technology Device
16 = /dev/ftlb FTL on second Memory Technology Device
@ -958,6 +975,7 @@ Your cooperation is appreciated.
191 = /dev/ippp63 64th SyncPPP device
255 = /dev/isdninfo ISDN monitor interface
45 block Parallel port IDE disk devices
0 = /dev/pda First parallel port IDE disk
16 = /dev/pdb Second parallel port IDE disk
@ -1044,6 +1062,7 @@ Your cooperation is appreciated.
1 = /dev/dcbri1 Second DataComm card
2 = /dev/dcbri2 Third DataComm card
3 = /dev/dcbri3 Fourth DataComm card
52 block Mylex DAC960 PCI RAID controller; fifth controller
0 = /dev/rd/c4d0 First disk, whole disk
8 = /dev/rd/c4d1 Second disk, whole disk
@ -1093,7 +1112,8 @@ Your cooperation is appreciated.
55 char DSP56001 digital signal processor
0 = /dev/dsp56k First DSP56001
55 block Mylex DAC960 PCI RAID controller; eigth controller
55 block Mylex DAC960 PCI RAID controller; eighth controller
0 = /dev/rd/c7d0 First disk, whole disk
8 = /dev/rd/c7d1 Second disk, whole disk
...
@ -1130,6 +1150,7 @@ Your cooperation is appreciated.
0 = /dev/cup0 Callout device for ttyP0
1 = /dev/cup1 Callout device for ttyP1
...
58 block Reserved for logical volume manager
59 char sf firewall package
@ -1149,6 +1170,7 @@ Your cooperation is appreciated.
NAMING CONFLICT -- PROPOSED REVISED NAME /dev/rpda0 etc
60-63 char LOCAL/EXPERIMENTAL USE
60-63 block LOCAL/EXPERIMENTAL USE
Allocated for local/experimental use. For devices not
assigned official numbers, these ranges should be
@ -1434,7 +1456,6 @@ Your cooperation is appreciated.
DAC960 (see major number 48) except that the limit on
partitions is 15.
78 char PAM Software's multimodem boards
0 = /dev/ttyM0 First PAM modem
1 = /dev/ttyM1 Second PAM modem
@ -1450,13 +1471,12 @@ Your cooperation is appreciated.
DAC960 (see major number 48) except that the limit on
partitions is 15.
79 char PAM Software's multimodem boards - alternate devices
0 = /dev/cum0 Callout device for ttyM0
1 = /dev/cum1 Callout device for ttyM1
...
79 block Compaq Intelligent Drive Array, eigth controller
79 block Compaq Intelligent Drive Array, eighth controller
0 = /dev/ida/c7d0 First logical drive whole disk
16 = /dev/ida/c7d1 Second logical drive whole disk
...
@ -1466,7 +1486,6 @@ Your cooperation is appreciated.
DAC960 (see major number 48) except that the limit on
partitions is 15.
80 char Photometrics AT200 CCD camera
0 = /dev/at200 Photometrics AT200 CCD camera
@ -1900,7 +1919,7 @@ Your cooperation is appreciated.
1 = /dev/av1 Second A/V card
...
111 block Compaq Next Generation Drive Array, eigth controller
111 block Compaq Next Generation Drive Array, eighth controller
0 = /dev/cciss/c7d0 First logical drive, whole disk
16 = /dev/cciss/c7d1 Second logical drive, whole disk
...
@ -1937,7 +1956,6 @@ Your cooperation is appreciated.
...
113 block IBM iSeries virtual CD-ROM
0 = /dev/iseries/vcda First virtual CD-ROM
1 = /dev/iseries/vcdb Second virtual CD-ROM
...
@ -2059,11 +2077,12 @@ Your cooperation is appreciated.
...
119 char VMware virtual network control
0 = /dev/vnet0 1st virtual network
1 = /dev/vnet1 2nd virtual network
0 = /dev/vmnet0 1st virtual network
1 = /dev/vmnet1 2nd virtual network
...
120-127 char LOCAL/EXPERIMENTAL USE
120-127 block LOCAL/EXPERIMENTAL USE
Allocated for local/experimental use. For devices not
assigned official numbers, these ranges should be
@ -2075,7 +2094,6 @@ Your cooperation is appreciated.
nodes; instead they should be accessed through the
/dev/ptmx cloning interface.
128 block SCSI disk devices (128-143)
0 = /dev/sddy 129th SCSI disk whole disk
16 = /dev/sddz 130th SCSI disk whole disk
@ -2087,7 +2105,6 @@ Your cooperation is appreciated.
disks (see major number 3) except that the limit on
partitions is 15.
129 block SCSI disk devices (144-159)
0 = /dev/sdeo 145th SCSI disk whole disk
16 = /dev/sdep 146th SCSI disk whole disk
@ -2123,7 +2140,6 @@ Your cooperation is appreciated.
disks (see major number 3) except that the limit on
partitions is 15.
132 block SCSI disk devices (192-207)
0 = /dev/sdgk 193rd SCSI disk whole disk
16 = /dev/sdgl 194th SCSI disk whole disk
@ -2135,7 +2151,6 @@ Your cooperation is appreciated.
disks (see major number 3) except that the limit on
partitions is 15.
133 block SCSI disk devices (208-223)
0 = /dev/sdha 209th SCSI disk whole disk
16 = /dev/sdhb 210th SCSI disk whole disk
@ -2147,7 +2162,6 @@ Your cooperation is appreciated.
disks (see major number 3) except that the limit on
partitions is 15.
134 block SCSI disk devices (224-239)
0 = /dev/sdhq 225th SCSI disk whole disk
16 = /dev/sdhr 226th SCSI disk whole disk
@ -2159,7 +2173,6 @@ Your cooperation is appreciated.
disks (see major number 3) except that the limit on
partitions is 15.
135 block SCSI disk devices (240-255)
0 = /dev/sdig 241st SCSI disk whole disk
16 = /dev/sdih 242nd SCSI disk whole disk
@ -2171,7 +2184,6 @@ Your cooperation is appreciated.
disks (see major number 3) except that the limit on
partitions is 15.
136-143 char Unix98 PTY slaves
0 = /dev/pts/0 First Unix98 pseudo-TTY
1 = /dev/pts/1 Second Unix98 pesudo-TTY
@ -2384,6 +2396,7 @@ Your cooperation is appreciated.
...
159 char RESERVED
159 block RESERVED
160 char General Purpose Instrument Bus (GPIB)
@ -2483,7 +2496,6 @@ Your cooperation is appreciated.
171 char Reserved for IEEE 1394 (Firewire)
172 char Moxa Intellio serial card
0 = /dev/ttyMX0 First Moxa port
1 = /dev/ttyMX1 Second Moxa port
@ -2543,9 +2555,6 @@ Your cooperation is appreciated.
64 = /dev/usb/rio500 Diamond Rio 500
65 = /dev/usb/usblcd USBLCD Interface (info@usblcd.de)
66 = /dev/usb/cpad0 Synaptics cPad (mouse/LCD)
67 = /dev/usb/adutux0 1st Ontrak ADU device
...
76 = /dev/usb/adutux10 10th Ontrak ADU device
96 = /dev/usb/hiddev0 1st USB HID device
...
111 = /dev/usb/hiddev15 16th USB HID device
@ -2558,7 +2567,7 @@ Your cooperation is appreciated.
132 = /dev/usb/idmouse ID Mouse (fingerprint scanner) device
133 = /dev/usb/sisusbvga1 First SiSUSB VGA device
...
140 = /dev/usb/sisusbvga8 Eigth SISUSB VGA device
140 = /dev/usb/sisusbvga8 Eighth SISUSB VGA device
144 = /dev/usb/lcd USB LCD device
160 = /dev/usb/legousbtower0 1st USB Legotower device
...
@ -2795,6 +2804,10 @@ Your cooperation is appreciated.
...
185 = /dev/ttyNX15 Hilscher netX serial port 15
186 = /dev/ttyJ0 JTAG1 DCC protocol based serial port emulation
187 = /dev/ttyUL0 Xilinx uartlite - port 0
...
190 = /dev/ttyUL3 Xilinx uartlite - port 3
191 = /dev/xvc0 Xen virtual console - port 0
205 char Low-density serial ports (alternate device)
0 = /dev/culu0 Callout device for ttyLU0
@ -2832,7 +2845,6 @@ Your cooperation is appreciated.
82 = /dev/cuvr0 Callout device for ttyVR0
83 = /dev/cuvr1 Callout device for ttyVR1
206 char OnStream SC-x0 tape devices
0 = /dev/osst0 First OnStream SCSI tape, mode 0
1 = /dev/osst1 Second OnStream SCSI tape, mode 0
@ -2922,7 +2934,6 @@ Your cooperation is appreciated.
...
212 char LinuxTV.org DVB driver subsystem
0 = /dev/dvb/adapter0/video0 first video decoder of first card
1 = /dev/dvb/adapter0/audio0 first audio decoder of first card
2 = /dev/dvb/adapter0/sec0 (obsolete/unused)
@ -3008,9 +3019,9 @@ Your cooperation is appreciated.
2 = /dev/3270/tub2 Second 3270 terminal
...
229 char IBM iSeries virtual console
0 = /dev/iseries/vtty0 First console port
1 = /dev/iseries/vtty1 Second console port
229 char IBM iSeries/pSeries virtual console
0 = /dev/hvc0 First console port
1 = /dev/hvc1 Second console port
...
230 char IBM iSeries virtual tape
@ -3083,12 +3094,14 @@ Your cooperation is appreciated.
234-239 UNASSIGNED
240-254 char LOCAL/EXPERIMENTAL USE
240-254 block LOCAL/EXPERIMENTAL USE
Allocated for local/experimental use. For devices not
assigned official numbers, these ranges should be
used in order to avoid conflicting with future assignments.
255 char RESERVED
255 block RESERVED
This major is reserved to assist the expansion to a
@ -3115,7 +3128,20 @@ Your cooperation is appreciated.
257 char Phoenix Technologies Cryptographic Services Driver
0 = /dev/ptlsec Crypto Services Driver
257 block SSFDC Flash Translation Layer filesystem
0 = /dev/ssfdca First SSFDC layer
8 = /dev/ssfdcb Second SSFDC layer
16 = /dev/ssfdcc Third SSFDC layer
24 = /dev/ssfdcd 4th SSFDC layer
32 = /dev/ssfdce 5th SSFDC layer
40 = /dev/ssfdcf 6th SSFDC layer
48 = /dev/ssfdcg 7th SSFDC layer
56 = /dev/ssfdch 8th SSFDC layer
258 block ROM/Flash read-only translation layer
0 = /dev/blockrom0 First ROM card's translation layer interface
1 = /dev/blockrom1 Second ROM card's translation layer interface
...
**** ADDITIONAL /dev DIRECTORY ENTRIES

View File

@ -1,99 +1,131 @@
Platform Devices and Drivers
~~~~~~~~~~~~~~~~~~~~~~~~~~~~
See <linux/platform_device.h> for the driver model interface to the
platform bus: platform_device, and platform_driver. This pseudo-bus
is used to connect devices on busses with minimal infrastructure,
like those used to integrate peripherals on many system-on-chip
processors, or some "legacy" PC interconnects; as opposed to large
formally specified ones like PCI or USB.
Platform devices
~~~~~~~~~~~~~~~~
Platform devices are devices that typically appear as autonomous
entities in the system. This includes legacy port-based devices and
host bridges to peripheral buses.
host bridges to peripheral buses, and most controllers integrated
into system-on-chip platforms. What they usually have in common
is direct addressing from a CPU bus. Rarely, a platform_device will
be connected through a segment of some other kind of bus; but its
registers will still be directly addressible.
Platform devices are given a name, used in driver binding, and a
list of resources such as addresses and IRQs.
struct platform_device {
const char *name;
u32 id;
struct device dev;
u32 num_resources;
struct resource *resource;
};
Platform drivers
~~~~~~~~~~~~~~~~
Drivers for platform devices are typically very simple and
unstructured. Either the device was present at a particular I/O port
and the driver was loaded, or it was not. There was no possibility
of hotplugging or alternative discovery besides probing at a specific
I/O address and expecting a specific response.
Platform drivers follow the standard driver model convention, where
discovery/enumeration is handled outside the drivers, and drivers
provide probe() and remove() methods. They support power management
and shutdown notifications using the standard conventions.
struct platform_driver {
int (*probe)(struct platform_device *);
int (*remove)(struct platform_device *);
void (*shutdown)(struct platform_device *);
int (*suspend)(struct platform_device *, pm_message_t state);
int (*suspend_late)(struct platform_device *, pm_message_t state);
int (*resume_early)(struct platform_device *);
int (*resume)(struct platform_device *);
struct device_driver driver;
};
Note that probe() should general verify that the specified device hardware
actually exists; sometimes platform setup code can't be sure. The probing
can use device resources, including clocks, and device platform_data.
Platform drivers register themselves the normal way:
int platform_driver_register(struct platform_driver *drv);
Or, in common situations where the device is known not to be hot-pluggable,
the probe() routine can live in an init section to reduce the driver's
runtime memory footprint:
int platform_driver_probe(struct platform_driver *drv,
int (*probe)(struct platform_device *))
Other Architectures, Modern Firmware, and new Platforms
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
These devices are not always at the legacy I/O ports. This is true on
other architectures and on some modern architectures. In most cases,
the drivers are modified to discover the devices at other well-known
ports for the given platform. However, the firmware in these systems
does usually know where exactly these devices reside, and in some
cases, it's the only way of discovering them.
Device Enumeration
~~~~~~~~~~~~~~~~~~
As a rule, platform specific (and often board-specific) setup code wil
register platform devices:
int platform_device_register(struct platform_device *pdev);
int platform_add_devices(struct platform_device **pdevs, int ndev);
The general rule is to register only those devices that actually exist,
but in some cases extra devices might be registered. For example, a kernel
might be configured to work with an external network adapter that might not
be populated on all boards, or likewise to work with an integrated controller
that some boards might not hook up to any peripherals.
In some cases, boot firmware will export tables describing the devices
that are populated on a given board. Without such tables, often the
only way for system setup code to set up the correct devices is to build
a kernel for a specific target board. Such board-specific kernels are
common with embedded and custom systems development.
In many cases, the memory and IRQ resources associated with the platform
device are not enough to let the device's driver work. Board setup code
will often provide additional information using the device's platform_data
field to hold additional information.
Embedded systems frequently need one or more clocks for platform devices,
which are normally kept off until they're actively needed (to save power).
System setup also associates those clocks with the device, so that that
calls to clk_get(&pdev->dev, clock_name) return them as needed.
The Platform Bus
~~~~~~~~~~~~~~~~
A platform bus has been created to deal with these issues. First and
foremost, it groups all the legacy devices under a common bus, and
gives them a common parent if they don't already have one.
Device Naming and Driver Binding
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The platform_device.dev.bus_id is the canonical name for the devices.
It's built from two components:
But, besides the organizational benefits, the platform bus can also
accommodate firmware-based enumeration.
* platform_device.name ... which is also used to for driver matching.
* platform_device.id ... the device instance number, or else "-1"
to indicate there's only one.
Device Discovery
~~~~~~~~~~~~~~~~
The platform bus has no concept of probing for devices. Devices
discovery is left up to either the legacy drivers or the
firmware. These entities are expected to notify the platform of
devices that it discovers via the bus's add() callback:
These are catenated, so name/id "serial"/0 indicates bus_id "serial.0", and
"serial/3" indicates bus_id "serial.3"; both would use the platform_driver
named "serial". While "my_rtc"/-1 would be bus_id "my_rtc" (no instance id)
and use the platform_driver called "my_rtc".
platform_bus.add(parent,bus_id).
Driver binding is performed automatically by the driver core, invoking
driver probe() after finding a match between device and driver. If the
probe() succeeds, the driver and device are bound as usual. There are
three different ways to find such a match:
- Whenever a device is registered, the drivers for that bus are
checked for matches. Platform devices should be registered very
early during system boot.
Bus IDs
~~~~~~~
Bus IDs are the canonical names for the devices. There is no globally
standard addressing mechanism for legacy devices. In the IA-32 world,
we have Pnp IDs to use, as well as the legacy I/O ports. However,
neither tell what the device really is or have any meaning on other
platforms.
- When a driver is registered using platform_driver_register(), all
unbound devices on that bus are checked for matches. Drivers
usually register later during booting, or by module loading.
Since both PnP IDs and the legacy I/O ports (and other standard I/O
ports for specific devices) have a 1:1 mapping, we map the
platform-specific name or identifier to a generic name (at least
within the scope of the kernel).
For example, a serial driver might find a device at I/O 0x3f8. The
ACPI firmware might also discover a device with PnP ID (_HID)
PNP0501. Both correspond to the same device and should be mapped to the
canonical name 'serial'.
The bus_id field should be a concatenation of the canonical name and
the instance of that type of device. For example, the device at I/O
port 0x3f8 should have a bus_id of "serial0". This places the
responsibility of enumerating devices of a particular type up to the
discovery mechanism. But, they are the entity that should know best
(as opposed to the platform bus driver).
Drivers
~~~~~~~
Drivers for platform devices should have a name that is the same as
the canonical name of the devices they support. This allows the
platform bus driver to do simple matching with the basic data
structures to determine if a driver supports a certain device.
For example, a legacy serial driver should have a name of 'serial' and
register itself with the platform bus.
Driver Binding
~~~~~~~~~~~~~~
Legacy drivers assume they are bound to the device once they start up
and probe an I/O port. Divorcing them from this will be a difficult
process. However, that shouldn't prevent us from implementing
firmware-based enumeration.
The firmware should notify the platform bus about devices before the
legacy drivers have had a chance to load. Once the drivers are loaded,
they driver model core will attempt to bind the driver to any
previously-discovered devices. Once that has happened, it will be free
to discover any other devices it pleases.
- Registering a driver using platform_driver_probe() works just like
using platform_driver_register(), except that the the driver won't
be probed later if another device registers. (Which is OK, since
this interface is only for use with non-hotpluggable devices.)

View File

@ -92,7 +92,7 @@ struct device represents a single device. It mainly contains metadata
describing the relationship the device has to other entities.
- Embedd a struct device in the bus-specific device type.
- Embed a struct device in the bus-specific device type.
struct pci_dev {

View File

@ -71,7 +71,7 @@ eliminating the need for any additional ioctls.
The disadvantage is that the driver/hardware has to manage the rest. For
the application programmer it would be as simple as sending/receiving an
array to/from the CI ioctls as defined in the Linux DVB API. No changes
have been made in the API to accomodate this feature.
have been made in the API to accommodate this feature.
* Why the need for another CI interface ?
@ -102,7 +102,7 @@ This CI interface follows the CI high level interface, which is not
implemented by most applications. Hence this area is revisited.
This CI interface is quite different in the case that it tries to
accomodate all other CI based devices, that fall into the other categories
accommodate all other CI based devices, that fall into the other categories.
This means that this CI interface handles the EN50221 style tags in the
Application layer only and no session management is taken care of by the

View File

@ -62,7 +62,7 @@ res : root device I/O resource
bus_base_addr : slot 0 address on this bus
slots : max slot number to probe
force_probe : Probe even when slot 0 is empty (no EISA mainboard)
dma_mask : Default DMA mask. Usualy the bridge device dma_mask.
dma_mask : Default DMA mask. Usually the bridge device dma_mask.
bus_nr : unique bus id, set by eisa_root_register
** Driver :

View File

@ -30,11 +30,39 @@ Who: Adrian Bunk <bunk@stusta.de>
---------------------------
What: raw1394: requests of type RAW1394_REQ_ISO_SEND, RAW1394_REQ_ISO_LISTEN
When: November 2006
Why: Deprecated in favour of the new ioctl-based rawiso interface, which is
more efficient. You should really be using libraw1394 for raw1394
access anyway.
Who: Jody McIntyre <scjody@modernduck.com>
When: June 2007
Why: Deprecated in favour of the more efficient and robust rawiso interface.
Affected are applications which use the deprecated part of libraw1394
(raw1394_iso_write, raw1394_start_iso_write, raw1394_start_iso_rcv,
raw1394_stop_iso_rcv) or bypass libraw1394.
Who: Dan Dennedy <dan@dennedy.org>, Stefan Richter <stefanr@s5r6.in-berlin.de>
---------------------------
What: dv1394 driver (CONFIG_IEEE1394_DV1394)
When: June 2007
Why: Replaced by raw1394 + userspace libraries, notably libiec61883. This
shift of application support has been indicated on www.linux1394.org
and developers' mailinglists for quite some time. Major applications
have been converted, with the exception of ffmpeg and hence xine.
Piped output of dvgrab2 is a partial equivalent to dv1394.
Who: Dan Dennedy <dan@dennedy.org>, Stefan Richter <stefanr@s5r6.in-berlin.de>
---------------------------
What: ieee1394 core's unused exports (CONFIG_IEEE1394_EXPORT_FULL_API)
When: January 2007
Why: There are no projects known to use these exported symbols, except
dfg1394 (uses one symbol whose functionality is core-internal now).
Who: Stefan Richter <stefanr@s5r6.in-berlin.de>
---------------------------
What: ieee1394's *_oui sysfs attributes (CONFIG_IEEE1394_OUI_DB)
When: January 2007
Files: drivers/ieee1394/: oui.db, oui2c.sh
Why: big size, little value
Who: Stefan Richter <stefanr@s5r6.in-berlin.de>
---------------------------
@ -53,18 +81,6 @@ Who: Mauro Carvalho Chehab <mchehab@brturbo.com.br>
---------------------------
What: sys_sysctl
When: January 2007
Why: The same information is available through /proc/sys and that is the
interface user space prefers to use. And there do not appear to be
any existing user in user space of sys_sysctl. The additional
maintenance overhead of keeping a set of binary names gets
in the way of doing a good job of maintaining this interface.
Who: Eric Biederman <ebiederm@xmission.com>
---------------------------
What: PCMCIA control ioctl (needed for pcmcia-cs [cardmgr, cardctl])
When: November 2005
Files: drivers/pcmcia/: pcmcia_ioctl.c
@ -82,18 +98,6 @@ Who: Dominik Brodowski <linux@brodo.de>
---------------------------
What: ip_queue and ip6_queue (old ipv4-only and ipv6-only netfilter queue)
When: December 2005
Why: This interface has been obsoleted by the new layer3-independent
"nfnetlink_queue". The Kernel interface is compatible, so the old
ip[6]tables "QUEUE" targets still work and will transparently handle
all packets into nfnetlink queue number 0. Userspace users will have
to link against API-compatible library on top of libnfnetlink_queue
instead of the current 'libipq'.
Who: Harald Welte <laforge@netfilter.org>
---------------------------
What: remove EXPORT_SYMBOL(kernel_thread)
When: August 2006
Files: arch/*/kernel/*_ksyms.c
@ -239,21 +243,6 @@ Who: Patrick McHardy <kaber@trash.net>
---------------------------
What: frame diverter
When: November 2006
Why: The frame diverter is included in most distribution kernels, but is
broken. It does not correctly handle many things:
- IPV6
- non-linear skb's
- network device RCU on removal
- input frames not correctly checked for protocol errors
It also adds allocation overhead even if not enabled.
It is not clear if anyone is still using it.
Who: Stephen Hemminger <shemminger@osdl.org>
---------------------------
What: PHYSDEVPATH, PHYSDEVBUS, PHYSDEVDRIVER in the uevent environment
When: October 2008
Why: The stacking of class devices makes these values misleading and
@ -273,10 +262,11 @@ Who: Jean Delvare <khali@linux-fr.org>
---------------------------
What: ftape
When: 2.6.20
Why: Orphaned for ages. SMP bugs long unfixed. Few users left
in the world.
Who: Jeff Garzik <jeff@garzik.org>
What: IPv4 only connection tracking/NAT/helpers
When: 2.6.22
Why: The new layer 3 independant connection tracking replaces the old
IPv4 only version. After some stabilization of the new code the
old one will be removed.
Who: Patrick McHardy <kaber@trash.net>
---------------------------

View File

@ -124,7 +124,7 @@ sync_fs: no no read
write_super_lockfs: ?
unlockfs: ?
statfs: no no no
remount_fs: no yes maybe (see below)
remount_fs: yes yes maybe (see below)
clear_inode: no
umount_begin: yes no no
show_options: no (vfsmount->sem)

View File

@ -209,7 +209,7 @@ will happen for write(2).
[struct config_group]
A config_item cannot live in a vaccum. The only way one can be created
A config_item cannot live in a vacuum. The only way one can be created
is via mkdir(2) on a config_group. This will trigger creation of a
child item.
@ -275,7 +275,7 @@ directory is not empty.
[struct configfs_subsystem]
A subsystem must register itself, ususally at module_init time. This
A subsystem must register itself, usually at module_init time. This
tells configfs to make the subsystem appear in the file tree.
struct configfs_subsystem {

View File

@ -51,6 +51,22 @@ homepage:
http://fuse.sourceforge.net/
Filesystem type
~~~~~~~~~~~~~~~
The filesystem type given to mount(2) can be one of the following:
'fuse'
This is the usual way to mount a FUSE filesystem. The first
argument of the mount system call may contain an arbitrary string,
which is not interpreted by the kernel.
'fuseblk'
The filesystem is block device based. The first argument of the
mount system call is interpreted as the name of the device.
Mount options
~~~~~~~~~~~~~
@ -94,6 +110,11 @@ Mount options
The default is infinite. Note that the size of read requests is
limited anyway to 32 pages (which is 128kbyte on i386).
'blksize=N'
Set the block size for the filesystem. The default is 512. This
option is only valid for 'fuseblk' type mounts.
Control filesystem
~~~~~~~~~~~~~~~~~~
@ -111,7 +132,7 @@ For each connection the following files exist within this directory:
'waiting'
The number of requests which are waiting to be transfered to
The number of requests which are waiting to be transferred to
userspace or being processed by the filesystem daemon. If there is
no filesystem activity and 'waiting' is non-zero, then the
filesystem is hung or deadlocked.
@ -136,7 +157,7 @@ following will happen:
2) If the request is not yet sent to userspace AND the signal is not
fatal, then an 'interrupted' flag is set for the request. When
the request has been successfully transfered to userspace and
the request has been successfully transferred to userspace and
this flag is set, an INTERRUPT request is queued.
3) If the request is already sent to userspace, then an INTERRUPT

View File

@ -274,7 +274,7 @@ History
Fixed race-condition in buffer code - it is in all filesystems in Linux;
when reading device (cat /dev/hda) while creating files on it, files
could be damaged
2.02 Woraround for bug in breada in Linux. breada could cause accesses beyond
2.02 Workaround for bug in breada in Linux. breada could cause accesses beyond
end of partition
2.03 Char, block devices and pipes are correctly created
Fixed non-crashing race in unlink (Alexander Viro)

View File

@ -337,7 +337,7 @@ Finally, for a mirrored volume, i.e. raid level 1, the table would look like
this (note all values are in 512-byte sectors):
--- cut here ---
# Ofs Size Raid Log Number Region Should Number Source Start Taget Start
# Ofs Size Raid Log Number Region Should Number Source Start Target Start
# in of the type type of log size sync? of Device in Device in
# vol volume params mirrors Device Device
0 2056320 mirror core 2 16 nosync 2 /dev/hda1 0 /dev/hdb1 0
@ -599,7 +599,7 @@ Note, a technical ChangeLog aimed at kernel hackers is in fs/ntfs/ChangeLog.
- Major bug fixes for reading files and volumes in corner cases which
were being hit by Windows 2k/XP users.
2.1.2:
- Major bug fixes aleviating the hangs in statfs experienced by some
- Major bug fixes alleviating the hangs in statfs experienced by some
users.
2.1.1:
- Update handling of compressed files so people no longer get the

View File

@ -30,7 +30,7 @@ Caveats
Features which OCFS2 does not support yet:
- sparse files
- extended attributes
- shared writeable mmap
- shared writable mmap
- loopback is supported, but data written will not
be cluster coherent.
- quotas

View File

@ -1220,9 +1220,9 @@ applications are using mlock(), or if you are running with no swap then
you probably should increase the lower_zone_protection setting.
The units of this tunable are fairly vague. It is approximately equal
to "megabytes". So setting lower_zone_protection=100 will protect around 100
to "megabytes," so setting lower_zone_protection=100 will protect around 100
megabytes of the lowmem zone from user allocations. It will also make
those 100 megabytes unavaliable for use by applications and by
those 100 megabytes unavailable for use by applications and by
pagecache, so there is a cost.
The effects of this tunable may be observed by monitoring
@ -1538,10 +1538,10 @@ TCP settings
tcp_ecn
-------
This file controls the use of the ECN bit in the IPv4 headers, this is a new
This file controls the use of the ECN bit in the IPv4 headers. This is a new
feature about Explicit Congestion Notification, but some routers and firewalls
block trafic that has this bit set, so it could be necessary to echo 0 to
/proc/sys/net/ipv4/tcp_ecn, if you want to talk to this sites. For more info
block traffic that has this bit set, so it could be necessary to echo 0 to
/proc/sys/net/ipv4/tcp_ecn if you want to talk to these sites. For more info
you could read RFC2481.
tcp_retrans_collapse

View File

@ -210,7 +210,7 @@ FILES
/signal2
The two signal notification channels of an SPU. These are read-write
files that operate on a 32 bit word. Writing to one of these files
triggers an interrupt on the SPU. The value writting to the signal
triggers an interrupt on the SPU. The value written to the signal
files can be read from the SPU through a channel read or from host user
space through the file. After the value has been read by the SPU, it
is reset to zero. The possible operations on an open signal1 or sig-

View File

@ -1,11 +1,8 @@
This is the implementation of the SystemV/Coherent filesystem for Linux.
It implements all of
- Xenix FS,
- SystemV/386 FS,
- Coherent FS.
This is version beta 4.
To install:
* Answer the 'System V and Coherent filesystem support' question with 'y'
when configuring the kernel.
@ -28,11 +25,173 @@ Bugs in the present implementation:
for this FS on hard disk yet.
Please report any bugs and suggestions to
Bruno Haible <haible@ma2s2.mathematik.uni-karlsruhe.de>
Pascal Haible <haible@izfm.uni-stuttgart.de>
Krzysztof G. Baranowski <kgb@manjak.knm.org.pl>
These filesystems are rather similar. Here is a comparison with Minix FS:
Bruno Haible
<haible@ma2s2.mathematik.uni-karlsruhe.de>
* Linux fdisk reports on partitions
- Minix FS 0x81 Linux/Minix
- Xenix FS ??
- SystemV FS ??
- Coherent FS 0x08 AIX bootable
* Size of a block or zone (data allocation unit on disk)
- Minix FS 1024
- Xenix FS 1024 (also 512 ??)
- SystemV FS 1024 (also 512 and 2048)
- Coherent FS 512
* General layout: all have one boot block, one super block and
separate areas for inodes and for directories/data.
On SystemV Release 2 FS (e.g. Microport) the first track is reserved and
all the block numbers (including the super block) are offset by one track.
* Byte ordering of "short" (16 bit entities) on disk:
- Minix FS little endian 0 1
- Xenix FS little endian 0 1
- SystemV FS little endian 0 1
- Coherent FS little endian 0 1
Of course, this affects only the file system, not the data of files on it!
* Byte ordering of "long" (32 bit entities) on disk:
- Minix FS little endian 0 1 2 3
- Xenix FS little endian 0 1 2 3
- SystemV FS little endian 0 1 2 3
- Coherent FS PDP-11 2 3 0 1
Of course, this affects only the file system, not the data of files on it!
* Inode on disk: "short", 0 means non-existent, the root dir ino is:
- Minix FS 1
- Xenix FS, SystemV FS, Coherent FS 2
* Maximum number of hard links to a file:
- Minix FS 250
- Xenix FS ??
- SystemV FS ??
- Coherent FS >=10000
* Free inode management:
- Minix FS a bitmap
- Xenix FS, SystemV FS, Coherent FS
There is a cache of a certain number of free inodes in the super-block.
When it is exhausted, new free inodes are found using a linear search.
* Free block management:
- Minix FS a bitmap
- Xenix FS, SystemV FS, Coherent FS
Free blocks are organized in a "free list". Maybe a misleading term,
since it is not true that every free block contains a pointer to
the next free block. Rather, the free blocks are organized in chunks
of limited size, and every now and then a free block contains pointers
to the free blocks pertaining to the next chunk; the first of these
contains pointers and so on. The list terminates with a "block number"
0 on Xenix FS and SystemV FS, with a block zeroed out on Coherent FS.
* Super-block location:
- Minix FS block 1 = bytes 1024..2047
- Xenix FS block 1 = bytes 1024..2047
- SystemV FS bytes 512..1023
- Coherent FS block 1 = bytes 512..1023
* Super-block layout:
- Minix FS
unsigned short s_ninodes;
unsigned short s_nzones;
unsigned short s_imap_blocks;
unsigned short s_zmap_blocks;
unsigned short s_firstdatazone;
unsigned short s_log_zone_size;
unsigned long s_max_size;
unsigned short s_magic;
- Xenix FS, SystemV FS, Coherent FS
unsigned short s_firstdatazone;
unsigned long s_nzones;
unsigned short s_fzone_count;
unsigned long s_fzones[NICFREE];
unsigned short s_finode_count;
unsigned short s_finodes[NICINOD];
char s_flock;
char s_ilock;
char s_modified;
char s_rdonly;
unsigned long s_time;
short s_dinfo[4]; -- SystemV FS only
unsigned long s_free_zones;
unsigned short s_free_inodes;
short s_dinfo[4]; -- Xenix FS only
unsigned short s_interleave_m,s_interleave_n; -- Coherent FS only
char s_fname[6];
char s_fpack[6];
then they differ considerably:
Xenix FS
char s_clean;
char s_fill[371];
long s_magic;
long s_type;
SystemV FS
long s_fill[12 or 14];
long s_state;
long s_magic;
long s_type;
Coherent FS
unsigned long s_unique;
Note that Coherent FS has no magic.
* Inode layout:
- Minix FS
unsigned short i_mode;
unsigned short i_uid;
unsigned long i_size;
unsigned long i_time;
unsigned char i_gid;
unsigned char i_nlinks;
unsigned short i_zone[7+1+1];
- Xenix FS, SystemV FS, Coherent FS
unsigned short i_mode;
unsigned short i_nlink;
unsigned short i_uid;
unsigned short i_gid;
unsigned long i_size;
unsigned char i_zone[3*(10+1+1+1)];
unsigned long i_atime;
unsigned long i_mtime;
unsigned long i_ctime;
* Regular file data blocks are organized as
- Minix FS
7 direct blocks
1 indirect block (pointers to blocks)
1 double-indirect block (pointer to pointers to blocks)
- Xenix FS, SystemV FS, Coherent FS
10 direct blocks
1 indirect block (pointers to blocks)
1 double-indirect block (pointer to pointers to blocks)
1 triple-indirect block (pointer to pointers to pointers to blocks)
* Inode size, inodes per block
- Minix FS 32 32
- Xenix FS 64 16
- SystemV FS 64 16
- Coherent FS 64 8
* Directory entry on disk
- Minix FS
unsigned short inode;
char name[14/30];
- Xenix FS, SystemV FS, Coherent FS
unsigned short inode;
char name[14];
* Dir entry size, dir entries per block
- Minix FS 16/32 64/32
- Xenix FS 16 64
- SystemV FS 16 64
- Coherent FS 16 32
* How to implement symbolic links such that the host fsck doesn't scream:
- Minix FS normal
- Xenix FS kludge: as regular files with chmod 1000
- SystemV FS ??
- Coherent FS kludge: as regular files with chmod 1000
Notation: We often speak of a "block" but mean a zone (the allocation unit)
and not the disk driver's notion of "block".

View File

@ -7,8 +7,17 @@ If you encounter problems with reading UDF discs using this driver,
please report them to linux_udf@hpesjro.fc.hp.com, which is the
developer's list.
Write support requires a block driver which supports writing. The current
scsi and ide cdrom drivers do not support writing.
Write support requires a block driver which supports writing. Currently
dvd+rw drives and media support true random sector writes, and so a udf
filesystem on such devices can be directly mounted read/write. CD-RW
media however, does not support this. Instead the media can be formatted
for packet mode using the utility cdrwtool, then the pktcdvd driver can
be bound to the underlying cd device to provide the required buffering
and read-modify-write cycles to allow the filesystem random sector writes
while providing the hardware with only full packet writes. While not
required for dvd+rw media, use of the pktcdvd driver often enhances
performance due to very poor read-modify-write support supplied internally
by drive firmware.
-------------------------------------------------------------------------------
The following mount options are supported:

View File

@ -1,307 +0,0 @@
Intro
=====
This file describes some issues involved when using the "ftape"
floppy tape device driver that comes with the Linux kernel.
ftape has a home page at
http://ftape.dot-heine.de/
which contains further information about ftape. Please cross check
this WWW address against the address given (if any) in the MAINTAINERS
file located in the top level directory of the Linux kernel source
tree.
NOTE: This is an unmaintained set of drivers, and it is not guaranteed to work.
If you are interested in taking over maintenance, contact Claus-Justus Heine
<ch@dot-heine.de>, the former maintainer.
Contents
========
A minus 1: Ftape documentation
A. Changes
1. Goal
2. I/O Block Size
3. Write Access when not at EOD (End Of Data) or BOT (Begin Of Tape)
4. Formatting
5. Interchanging cartridges with other operating systems
B. Debugging Output
1. Introduction
2. Tuning the debugging output
C. Boot and load time configuration
1. Setting boot time parameters
2. Module load time parameters
3. Ftape boot- and load time options
4. Example kernel parameter setting
5. Example module parameter setting
D. Support and contacts
*******************************************************************************
A minus 1. Ftape documentation
==============================
Unluckily, the ftape-HOWTO is out of date. This really needs to be
changed. Up to date documentation as well as recent development
versions of ftape and useful links to related topics can be found at
the ftape home page at
http://ftape.dot-heine.de/
*******************************************************************************
A. Changes
==========
1. Goal
~~~~
The goal of all that incompatibilities was to give ftape an interface
that resembles the interface provided by SCSI tape drives as close
as possible. Thus any Unix backup program that is known to work
with SCSI tape drives should also work.
The concept of a fixed block size for read/write transfers is
rather unrelated to this SCSI tape compatibility at the file system
interface level. It developed out of a feature of zftape, a
block wise user transparent on-the-fly compression. That compression
support will not be dropped in future releases for compatibility
reasons with previous releases of zftape.
2. I/O Block Size
~~~~~~~~~~~~~~
The block size defaults to 10k which is the default block size of
GNU tar.
The block size can be tuned either during kernel configuration or
at runtime with the MTIOCTOP ioctl using the MTSETBLK operation
(i.e. do "mt -f /dev/qft0" setblk #BLKSZ). A block size of 0
switches to variable block size mode i.e. "mt setblk 0" switches
off the block size restriction. However, this disables zftape's
built in on-the-fly compression which doesn't work with variable
block size mode.
The BLKSZ parameter must be given as a byte count and must be a
multiple of 32k or 0, i.e. use "mt setblk 32768" to switch to a
block size of 32k.
The typical symptom of a block size mismatch is an "invalid
argument" error message.
3. Write Access when not at EOD (End Of Data) or BOT (Begin Of Tape)
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
zftape (the file system interface of ftape-3.x) denies write access
to the tape cartridge when it isn't positioned either at BOT or
EOD.
4. Formatting
~~~~~~~~~~
ftape DOES support formatting of floppy tape cartridges. You need the
`ftformat' program that is shipped with the modules version of ftape.
Please get the latest version of ftape from
ftp://sunsite.unc.edu/pub/Linux/kernel/tapes
or from the ftape home page at
http://ftape.dot-heine.de/
`ftformat' is contained in the `./contrib/' subdirectory of that
separate ftape package.
5. Interchanging cartridges with other operating systems
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The internal emulation of Unix tape device file marks has changed
completely. ftape now uses the volume table segment as specified
by the QIC-40/80/3010/3020/113 standards to emulate file marks. As
a consequence there is limited support to interchange cartridges
with other operating systems.
To be more precise: ftape will detect volumes written by other OS's
programs and other OS's programs will detect volumes written by
ftape.
However, it isn't possible to extract the data dumped to the tape
by some MSDOS program with ftape. This exceeds the scope of a
kernel device driver. If you need such functionality, then go ahead
and write a user space utility that is able to do that. ftape already
provides all kernel level support necessary to do that.
*******************************************************************************
B. Debugging Output
================
1. Introduction
~~~~~~~~~~~~
The ftape driver can be very noisy in that is can print lots of
debugging messages to the kernel log files and the system console.
While this is useful for debugging it might be annoying during
normal use and enlarges the size of the driver by several kilobytes.
To reduce the size of the driver you can trim the maximal amount of
debugging information available during kernel configuration. Please
refer to the kernel configuration script and its on-line help
functionality.
The amount of debugging output maps to the "tracing" boot time
option and the "ft_tracing" modules option as follows:
0 bugs
1 + errors (with call-stack dump)
2 + warnings
3 + information
4 + more information
5 + program flow
6 + fdc/dma info
7 + data flow
8 + everything else
2. Tuning the debugging output
~~~~~~~~~~~~~~~~~~~~~~~~~~~
To reduce the amount of debugging output printed to the system
console you can
i) trim the debugging output at run-time with
mt -f /dev/nqft0 setdensity #DBGLVL
where "#DBGLVL" is a number between 0 and 9
ii) trim the debugging output at module load time with
modprobe ftape ft_tracing=#DBGLVL
Of course, this applies only if you have configured ftape to be
compiled as a module.
iii) trim the debugging output during system boot time. Add the
following to the kernel command line:
ftape=#DBGLVL,tracing
Please refer also to the next section if you don't know how to
set boot time parameters.
*******************************************************************************
C. Boot and load time configuration
================================
1. Setting boot time parameters
~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Assuming that you use lilo, the LI)nux LO)ader, boot time kernel
parameters can be set by adding a line
append some_kernel_boot_time_parameter
to `/etc/lilo.conf' or at real boot time by typing in the options
at the prompt provided by LILO. I can't give you advice on how to
specify those parameters with other loaders as I don't use them.
For ftape, each "some_kernel_boot_time_parameter" looks like
"ftape=value,option". As an example, the debugging output can be
increased with
ftape=4,tracing
NOTE: the value precedes the option name.
2. Module load time parameters
~~~~~~~~~~~~~~~~~~~~~~~~~~~
Module parameters can be specified either directly when invoking
the program 'modprobe' at the shell prompt:
modprobe ftape ft_tracing=4
or by editing the file `/etc/modprobe.conf' in which case they take
effect each time when the module is loaded with `modprobe' (please
refer to the respective manual pages). Thus, you should add a line
options ftape ft_tracing=4
to `/etc/modprobe.conf` if you intend to increase the debugging
output of the driver.
3. Ftape boot- and load time options
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
i. Controlling the amount of debugging output
DBGLVL has to be replaced by a number between 0 and 8.
module | kernel command line
-----------------------|----------------------
ft_tracing=DBGLVL | ftape=DBGLVL,tracing
ii. Hardware setup
BASE is the base address of your floppy disk controller,
IRQ and DMA give its interrupt and DMA channel, respectively.
BOOL is an integer, "0" means "no"; any other value means
"yes". You don't need to specify anything if connecting your tape
drive to the standard floppy disk controller. All of these
values have reasonable defaults. The defaults can be modified
during kernel configuration, i.e. while running "make config",
"make menuconfig" or "make xconfig" in the top level directory
of the Linux kernel source tree. Please refer also to the on
line documentation provided during that kernel configuration
process.
ft_probe_fc10 is set to a non-zero value if you wish for ftape to
probe for a Colorado FC-10 or FC-20 controller.
ft_mach2 is set to a non-zero value if you wish for ftape to probe
for a Mountain MACH-2 controller.
module | kernel command line
-----------------------|----------------------
ft_fdc_base=BASE | ftape=BASE,ioport
ft_fdc_irq=IRQ | ftape=IRQ,irq
ft_fdc_dma=DMA | ftape=DMA,dma
ft_probe_fc10=BOOL | ftape=BOOL,fc10
ft_mach2=BOOL | ftape=BOOL,mach2
ft_fdc_threshold=THR | ftape=THR,threshold
ft_fdc_rate_limit=RATE | ftape=RATE,datarate
4. Example kernel parameter setting
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
To configure ftape to probe for a Colorado FC-10/FC-20 controller
and to increase the amount of debugging output a little bit, add
the following line to `/etc/lilo.conf':
append ftape=1,fc10 ftape=4,tracing
5. Example module parameter setting
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
To do the same, but with ftape compiled as a loadable kernel
module, add the following line to `/etc/modprobe.conf':
options ftape ft_probe_fc10=1 ft_tracing=4
*******************************************************************************
D. Support and contacts
====================
Ftape is distributed under the GNU General Public License. There is
absolutely no warranty for this software. However, you can reach
the current maintainer of the ftape package under the email address
given in the MAINTAINERS file which is located in the top level
directory of the Linux kernel source tree. There you'll find also
the relevant mailing list to use as a discussion forum and the web
page to query for the most recent documentation, related work and
development versions of ftape.
Changelog:
==========
~1996: Original Document
10-24-2004: General cleanup and updating, noting additional module options.
James Nelson <james4765@gmail.com>

View File

@ -59,7 +59,7 @@ the following things on the "Kernel Hacking" tab:
Then build as usual, download to the board and execute. Note that if
"Immediate activation" was selected, then the kernel will wait for GDB to
attach. If not, then the kernel will boot immediately and GDB will have to
interupt it or wait for an exception to occur if before doing anything with
interrupt it or wait for an exception to occur before doing anything with
the kernel.

View File

@ -156,7 +156,7 @@ with the main kernel in this regard. Hence the debug mode code (gdbstub) is
almost completely self-contained. The only external code used is the
sprintf family of functions.
Futhermore, break.S is so complicated because single-step mode does not
Furthermore, break.S is so complicated because single-step mode does not
switch off on entry to an exception. That means unless manually disabled,
single-stepping will blithely go on stepping into things like interrupts.
See gdbstub.txt for more information.

View File

@ -2,7 +2,7 @@
----------------------------
H. Peter Anvin <hpa@zytor.com>
Last update 2005-09-02
Last update 2006-11-17
On the i386 platform, the Linux kernel uses a rather complicated boot
convention. This has evolved partially due to historical aspects, as
@ -35,6 +35,8 @@ Protocol 2.03: (Kernel 2.4.18-pre1) Explicitly makes the highest possible
initrd address available to the bootloader.
Protocol 2.04: (Kernel 2.6.14) Extend the syssize field to four bytes.
Protocol 2.05: (Kernel 2.6.20) Make protected mode kernel relocatable.
Introduce relocatable_kernel and kernel_alignment fields.
**** MEMORY LAYOUT
@ -129,6 +131,8 @@ Offset Proto Name Meaning
0226/2 N/A pad1 Unused
0228/4 2.02+ cmd_line_ptr 32-bit pointer to the kernel command line
022C/4 2.03+ initrd_addr_max Highest legal initrd address
0230/4 2.05+ kernel_alignment Physical addr alignment required for kernel
0234/1 2.05+ relocatable_kernel Whether kernel is relocatable or not
(1) For backwards compatibility, if the setup_sects field contains 0, the
real value is 4.

View File

@ -390,5 +390,5 @@ mlord@pobox.com
Wed Apr 17 22:52:44 CEST 2002 edited by Marcin Dalecki, the current
maintainer.
Wed Aug 20 22:31:29 CEST 2003 updated ide boot uptions to current ide.c
Wed Aug 20 22:31:29 CEST 2003 updated ide boot options to current ide.c
comments at 2.6.0-test4 time. Maciej Soltysiak <solt@dns.toxicfilms.tv>

View File

@ -91,8 +91,8 @@ JOY1DAT Y7 Y6 Y5 Y4 Y3 Y2 Y1 Y0 X7 X6 X5 X4 X3 X2 X1 X0
| 1 | M0HQ | JOY0DAT Horizontal Clock (quadrature) |
| 2 | M0V | JOY0DAT Vertical Clock |
| 3 | M0VQ | JOY0DAT Vertical Clock (quadrature) |
| 4 | M1V | JOY1DAT Horizontall Clock |
| 5 | M1VQ | JOY1DAT Horizontall Clock (quadrature) |
| 4 | M1V | JOY1DAT Horizontal Clock |
| 5 | M1VQ | JOY1DAT Horizontal Clock (quadrature) |
| 6 | M1V | JOY1DAT Vertical Clock |
| 7 | M1VQ | JOY1DAT Vertical Clock (quadrature) |
+--------+----------+-----------------------------------------+

View File

@ -103,7 +103,7 @@ LEFT=0x74 & RIGHT=0x75).
5.1 Joystick Event Reporting
In this mode, the ikbd generates a record whever the joystick position is
In this mode, the ikbd generates a record whenever the joystick position is
changed (i.e. for each opening or closing of a joystick switch or trigger).
The joystick event record is two bytes of the form:
@ -277,8 +277,8 @@ default to 1 at RESET (or power-up).
9.7 SET MOUSE SCALE
0x0C
X ; horizontal mouse ticks per internel X
Y ; vertical mouse ticks per internel Y
X ; horizontal mouse ticks per internal X
Y ; vertical mouse ticks per internal Y
This command sets the scale factor for the ABSOLUTE MOUSE POSITIONING mode.
In this mode, the specified number of mouse phase changes ('clicks') must
@ -323,7 +323,7 @@ mouse position.
0x0F
This command makes the origin of the Y axis to be at the bottom of the
logical coordinate system internel to the ikbd for all relative or absolute
logical coordinate system internal to the ikbd for all relative or absolute
mouse motion. This causes mouse motion toward the user to be negative in sign
and away from the user to be positive.
@ -597,8 +597,8 @@ mode or FIRE BUTTON MONITORING mode.
10. SCAN CODES
The key scan codes return by the ikbd are chosen to simplify the
implementaion of GSX.
The key scan codes returned by the ikbd are chosen to simplify the
implementation of GSX.
GSX Standard Keyboard Mapping.

View File

@ -134,7 +134,7 @@ Reading /sys/../lineX will return the format string with its current value:
888888888888
Linux Rocks!
Writing to /sys/../lineX will set the coresponding LCD line.
Writing to /sys/../lineX will set the corresponding LCD line.
- Excess characters are ignored.
- If less characters are written than allowed, the remaining digits are
unchanged.

View File

@ -735,7 +735,7 @@ CDROM_DISC_STATUS Get disc type, etc.
Ok, this is where problems start. The current interface for
the CDROM_DISC_STATUS ioctl is flawed. It makes the false
assumption that CDs are all CDS_DATA_1 or all CDS_AUDIO, etc.
Unfortunatly, while this is often the case, it is also
Unfortunately, while this is often the case, it is also
very common for CDs to have some tracks with data, and some
tracks with audio. Just because I feel like it, I declare
the following to be the best way to cope. If the CD has

View File

@ -227,9 +227,9 @@ more details, with real examples.
be included in a library, lib.a.
All objects listed with lib-y are combined in a single
library for that directory.
Objects that are listed in obj-y and additionaly listed in
lib-y will not be included in the library, since they will anyway
be accessible.
Objects that are listed in obj-y and additionally listed in
lib-y will not be included in the library, since they will
be accessible anyway.
For consistency, objects listed in lib-m will be included in lib.a.
Note that the same kbuild makefile may list files to be built-in
@ -535,7 +535,7 @@ Both possibilities are described in the following.
Host programs can be made up based on composite objects.
The syntax used to define composite objects for host programs is
similar to the syntax used for kernel objects.
$(<executeable>-objs) lists all objects used to link the final
$(<executable>-objs) lists all objects used to link the final
executable.
Example:
@ -1022,7 +1022,7 @@ When kbuild executes, the following steps are followed (roughly):
In this example, there are two possible targets, requiring different
options to the linker. The linker options are specified using the
LDFLAGS_$@ syntax - one for each potential target.
$(targets) are assinged all potential targets, by which kbuild knows
$(targets) are assigned all potential targets, by which kbuild knows
the targets and will:
1) check for commandline changes
2) delete target during make clean

View File

@ -164,6 +164,10 @@ and is between 256 and 4096 characters. It is defined in the file
acpi_skip_timer_override [HW,ACPI]
Recognize and ignore IRQ0/pin2 Interrupt Override.
For broken nForce2 BIOS resulting in XT-PIC timer.
acpi_use_timer_override [HW,ACPI}
Use timer override. For some broken Nvidia NF5 boards
that require a timer override, but don't have
HPET
acpi_dbg_layer= [HW,ACPI]
Format: <int>
@ -553,9 +557,6 @@ and is between 256 and 4096 characters. It is defined in the file
floppy= [HW]
See Documentation/floppy.txt.
ftape= [HW] Floppy Tape subsystem debugging options.
See Documentation/ftape.txt.
gamecon.map[2|3]=
[HW,JOY] Multisystem joystick and NES/SNES/PSX pad
support via parallel port (up to 5 devices per port)
@ -598,8 +599,6 @@ and is between 256 and 4096 characters. It is defined in the file
hugepages= [HW,IA-32,IA-64] Maximal number of HugeTLB pages.
noirqbalance [IA-32,SMP,KNL] Disable kernel irq balancing
i8042.direct [HW] Put keyboard port into non-translated mode
i8042.dumbkbd [HW] Pretend that controller can only read data from
keyboard and cannot control its state
@ -649,6 +648,10 @@ and is between 256 and 4096 characters. It is defined in the file
idle= [HW]
Format: idle=poll or idle=halt
ignore_loglevel [KNL]
Ignore loglevel setting - this will print /all/
kernel messages to the console. Useful for debugging.
ihash_entries= [KNL]
Set number of hash buckets for inode cache.
@ -713,7 +716,12 @@ and is between 256 and 4096 characters. It is defined in the file
Format: <RDP>,<reset>,<pci_scan>,<verbosity>
isolcpus= [KNL,SMP] Isolate CPUs from the general scheduler.
Format: <cpu number>,...,<cpu number>
Format:
<cpu number>,...,<cpu number>
or
<cpu number>-<cpu number> (must be a positive range in ascending order)
or a mixture
<cpu number>,...,<cpu number>-<cpu number>
This option can be used to specify one or more CPUs
to isolate from the general SMP balancing and scheduling
algorithms. The only way to move a process onto or off
@ -1011,6 +1019,10 @@ and is between 256 and 4096 characters. It is defined in the file
emulation library even if a 387 maths coprocessor
is present.
noaliencache [MM, NUMA] Disables the allcoation of alien caches in
the slab allocator. Saves per-node memory, but will
impact performance on real NUMA hardware.
noalign [KNL,ARM]
noapic [SMP,APIC] Tells the kernel to not make use of any
@ -1051,9 +1063,14 @@ and is between 256 and 4096 characters. It is defined in the file
in certain environments such as networked servers or
real-time systems.
noirqbalance [IA-32,SMP,KNL] Disable kernel irq balancing
noirqdebug [IA-32] Disables the code which attempts to detect and
disable unhandled interrupt sources.
no_timer_check [IA-32,X86_64,APIC] Disables the code which tests for
broken timer IRQ sources.
noisapnp [ISAPNP] Disables ISA PnP code.
noinitrd [RAM] Tells the kernel not to load any configured
@ -1284,6 +1301,7 @@ and is between 256 and 4096 characters. It is defined in the file
Param: "schedule" - profile schedule points.
Param: <number> - step/bucket size as a power of 2 for
statistical time based profiling.
Param: "sleep" - profile D-state sleeping (millisecs)
processor.max_cstate= [HW,ACPI]
Limit processor to maximum C-state
@ -1365,6 +1383,12 @@ and is between 256 and 4096 characters. It is defined in the file
resume= [SWSUSP]
Specify the partition device for software suspend
resume_offset= [SWSUSP]
Specify the offset from the beginning of the partition
given by "resume=" at which the swap header is located,
in <PAGE_SIZE> units (needed only for swap files).
See Documentation/power/swsusp-and-swap-files.txt
rhash_entries= [KNL,NET]
Set number of hash buckets for route cache
@ -1415,6 +1439,11 @@ and is between 256 and 4096 characters. It is defined in the file
scsi_logging= [SCSI]
scsi_mod.scan= [SCSI] sync (default) scans SCSI busses as they are
discovered. async scans them in kernel threads,
allowing boot to proceed. none ignores them, expecting
user space to do the scan.
selinux [SELINUX] Disable or enable SELinux at boot time.
Format: { "0" | "1" }
See security/selinux/Kconfig help text.
@ -1726,6 +1755,9 @@ and is between 256 and 4096 characters. It is defined in the file
norandmaps Don't use address space randomization
Equivalent to echo 0 > /proc/sys/kernel/randomize_va_space
unwind_debug=N N > 0 will enable dwarf2 unwinder debugging
This is useful to get more information why
you got a "dwarf2 unwinder stuck"
______________________________________________________________________

View File

@ -304,7 +304,7 @@ about the status of the key service:
R Revoked
D Dead
Q Contributes to user's quota
U Under contruction by callback to userspace
U Under construction by callback to userspace
N Negative key
This file must be enabled at kernel configuration time as it allows anyone

View File

@ -442,9 +442,10 @@ static int __init kprobe_init(void)
kp.fault_handler = handler_fault;
kp.symbol_name = "do_fork";
if ((ret = register_kprobe(&kp) < 0)) {
ret = register_kprobe(&kp);
if (ret < 0) {
printk("register_kprobe failed, returned %d\n", ret);
return -1;
return ret;
}
printk("kprobe registered\n");
return 0;

View File

@ -121,7 +121,7 @@ contains the following options:
MAX_AGE:
Maximum time, in seconds, of hard drive spindown time that you are
confortable with. Worst case, it's possible that you could lose this
comfortable with. Worst case, it's possible that you could lose this
amount of work if your battery fails while you're in laptop mode.
MINIMUM_BATTERY_MINUTES:
@ -235,7 +235,7 @@ It should be installed as /etc/default/laptop-mode on Debian, and as
--------------------CONFIG FILE BEGIN-------------------------------------------
# Maximum time, in seconds, of hard drive spindown time that you are
# confortable with. Worst case, it's possible that you could lose this
# comfortable with. Worst case, it's possible that you could lose this
# amount of work if your battery fails you while in laptop mode.
#MAX_AGE=600
@ -350,7 +350,7 @@ fi
# set defaults instead:
# Maximum time, in seconds, of hard drive spindown time that you are
# confortable with. Worst case, it's possible that you could lose this
# comfortable with. Worst case, it's possible that you could lose this
# amount of work if your battery fails you while in laptop mode.
MAX_AGE=${MAX_AGE:-'600'}
@ -699,7 +699,7 @@ ACPI integration
Dax Kelson submitted this so that the ACPI acpid daemon will
kick off the laptop_mode script and run hdparm. The part that
automatically disables laptop mode when the battery is low was
writen by Jan Topinski.
written by Jan Topinski.
-----------------/etc/acpi/events/ac_adapter BEGIN------------------------------
event=ac_adapter

View File

@ -212,7 +212,7 @@ There are some minimal guarantees that may be expected of a CPU:
STORE *X = c, d = LOAD *X
(Loads and stores overlap if they are targetted at overlapping pieces of
(Loads and stores overlap if they are targeted at overlapping pieces of
memory).
And there are a number of things that _must_ or _must_not_ be assumed:
@ -1016,7 +1016,7 @@ There are some more advanced barrier functions:
(*) set_mb(var, value)
This assigns the value to the variable and then inserts at least a write
This assigns the value to the variable and then inserts a full memory
barrier after it, depending on the function. It isn't guaranteed to
insert anything more than a compiler barrier in a UP compilation.

View File

@ -58,6 +58,8 @@ fore200e.txt
- FORE Systems PCA-200E/SBA-200E ATM NIC driver info.
framerelay.txt
- info on using Frame Relay/Data Link Connection Identifier (DLCI).
generic_netlink.txt
- info on Generic Netlink
ip-sysctl.txt
- /proc/sys/net/ipv4/* variables
ip_dynaddr.txt

View File

@ -95,8 +95,8 @@ There are two types of event register ACK mechanisms.
Move all to dev->poll()
C) Ability to detect new work correctly.
NAPI works by shutting down event interrupts when theres work and
turning them on when theres none.
NAPI works by shutting down event interrupts when there's work and
turning them on when there's none.
New packets might show up in the small window while interrupts were being
re-enabled (refer to appendix 2). A packet might sneak in during the period
we are enabling interrupts. We only get to know about such a packet when the
@ -114,7 +114,7 @@ Locking rules and environmental guarantees
only one CPU can pick the initial interrupt and hence the initial
netif_rx_schedule(dev);
- The core layer invokes devices to send packets in a round robin format.
This implies receive is totaly lockless because of the guarantee only that
This implies receive is totally lockless because of the guarantee that only
one CPU is executing it.
- contention can only be the result of some other CPU accessing the rx
ring. This happens only in close() and suspend() (when these methods
@ -510,7 +510,7 @@ static int my_poll (struct net_device *dev, int *budget)
an interrupt will be generated */
goto done;
}
/* done! at least thats what it looks like ;->
/* done! at least that's what it looks like ;->
if new packets came in after our last check on status bits
they'll be caught by the while check and we go back and clear them
since we havent exceeded our quota */
@ -535,11 +535,11 @@ done:
* 1. it can race with disabling irqs in irq handler (which are done to
* schedule polls)
* 2. it can race with dis/enabling irqs in other poll threads
* 3. if an irq raised after the begining of the outer beginning
* 3. if an irq raised after the beginning of the outer beginning
* loop (marked in the code above), it will be immediately
* triggered here.
*
* Summarizing: the logic may results in some redundant irqs both
* Summarizing: the logic may result in some redundant irqs both
* due to races in masking and due to too late acking of already
* processed irqs. The good news: no events are ever lost.
*/
@ -601,7 +601,7 @@ a)
5) dev->close() and dev->suspend() issues
==========================================
The driver writter neednt worry about this. The top net layer takes
The driver writer needn't worry about this; the top net layer takes
care of it.
6) Adding new Stats to /proc
@ -622,9 +622,9 @@ FC should be programmed to apply in the case when the system cant pull out
packets fast enough i.e send a pause only when you run out of rx buffers.
Note FC in itself is a good solution but we have found it to not be
much of a commodity feature (both in NICs and switches) and hence falls
under the same category as using NIC based mitigation. Also experiments
indicate that its much harder to resolve the resource allocation
issue (aka lazy receiving that NAPI offers) and hence quantify its usefullness
under the same category as using NIC based mitigation. Also, experiments
indicate that it's much harder to resolve the resource allocation
issue (aka lazy receiving that NAPI offers) and hence quantify its usefulness
proved harder. In any case, FC works even better with NAPI but is not
necessary.
@ -678,10 +678,10 @@ routine:
CSR5 bit of interest is only the rx status.
If you look at the last if statement:
you just finished grabbing all the packets from the rx ring .. you check if
status bit says theres more packets just in ... it says none; you then
status bit says there are more packets just in ... it says none; you then
enable rx interrupts again; if a new packet just came in during this check,
we are counting that CSR5 will be set in that small window of opportunity
and that by re-enabling interrupts, we would actually triger an interrupt
and that by re-enabling interrupts, we would actually trigger an interrupt
to register the new packet for processing.
[The above description nay be very verbose, if you have better wording

View File

@ -620,8 +620,8 @@ I/O Address Device IRQ Device
12 Mouse (PS/2)
Memory Address Device 13 Math Coprocessor
-------------- --------------------- 14 Hard Disk controller
A000-BFFF EGA Graphics Adpater
A000-C7FF VGA Graphics Adpater
A000-BFFF EGA Graphics Adapter
A000-C7FF VGA Graphics Adapter
B000-BFFF Mono Graphics Adapter
B800-BFFF Color Graphics Adapter
E000-FFFF AT BIOS

View File

@ -19,21 +19,17 @@ for real time and multimedia traffic.
It has a base protocol and pluggable congestion control IDs (CCIDs).
It is at draft RFC status and the homepage for DCCP as a protocol is at:
http://www.icir.org/kohler/dcp/
It is at experimental RFC status and the homepage for DCCP as a protocol is at:
http://www.read.cs.ucla.edu/dccp/
Missing features
================
The DCCP implementation does not currently have all the features that are in
the draft RFC.
the RFC.
In particular the following are missing:
- CCID2 support
- feature negotiation
When testing against other implementations it appears that elapsed time
options are not coded compliant to the specification.
The known bugs are at:
http://linux-net.osdl.org/index.php/TODO#DCCP
Socket options
==============
@ -47,12 +43,70 @@ the socket will fall back to 0 (which means that no meaningful service code
is present). Connecting sockets set at most one service option; for
listening sockets, multiple service codes can be specified.
DCCP_SOCKOPT_SEND_CSCOV and DCCP_SOCKOPT_RECV_CSCOV are used for setting the
partial checksum coverage (RFC 4340, sec. 9.2). The default is that checksums
always cover the entire packet and that only fully covered application data is
accepted by the receiver. Hence, when using this feature on the sender, it must
be enabled at the receiver, too with suitable choice of CsCov.
DCCP_SOCKOPT_SEND_CSCOV sets the sender checksum coverage. Values in the
range 0..15 are acceptable. The default setting is 0 (full coverage),
values between 1..15 indicate partial coverage.
DCCP_SOCKOPT_SEND_CSCOV is for the receiver and has a different meaning: it
sets a threshold, where again values 0..15 are acceptable. The default
of 0 means that all packets with a partial coverage will be discarded.
Values in the range 1..15 indicate that packets with minimally such a
coverage value are also acceptable. The higher the number, the more
restrictive this setting (see [RFC 4340, sec. 9.2.1]).
Sysctl variables
================
Several DCCP default parameters can be managed by the following sysctls
(sysctl net.dccp.default or /proc/sys/net/dccp/default):
request_retries
The number of active connection initiation retries (the number of
Requests minus one) before timing out. In addition, it also governs
the behaviour of the other, passive side: this variable also sets
the number of times DCCP repeats sending a Response when the initial
handshake does not progress from RESPOND to OPEN (i.e. when no Ack
is received after the initial Request). This value should be greater
than 0, suggested is less than 10. Analogue of tcp_syn_retries.
retries1
How often a DCCP Response is retransmitted until the listening DCCP
side considers its connecting peer dead. Analogue of tcp_retries1.
retries2
The number of times a general DCCP packet is retransmitted. This has
importance for retransmitted acknowledgments and feature negotiation,
data packets are never retransmitted. Analogue of tcp_retries2.
send_ndp = 1
Whether or not to send NDP count options (sec. 7.7.2).
send_ackvec = 1
Whether or not to send Ack Vector options (sec. 11.5).
ack_ratio = 2
The default Ack Ratio (sec. 11.3) to use.
tx_ccid = 2
Default CCID for the sender-receiver half-connection.
rx_ccid = 2
Default CCID for the receiver-sender half-connection.
seq_window = 100
The initial sequence window (sec. 7.5.2).
tx_qlen = 5
The size of the transmit buffer in packets. A value of 0 corresponds
to an unbounded transmit buffer.
Notes
=====
SELinux does not yet have support for DCCP. You will need to turn it off or
else you will get EACCES.
DCCP does not travel through NAT successfully at present. This is because
the checksum covers the psuedo-header as per TCP and UDP. It should be
relatively trivial to add Linux NAT support for DCCP.
DCCP does not travel through NAT successfully at present on many boxes. This is
because the checksum covers the psuedo-header as per TCP and UDP. Linux NAT
support for DCCP has been added.

View File

@ -1,7 +1,7 @@
Linux* Base Driver for the Intel(R) PRO/1000 Family of Adapters
===============================================================
November 15, 2005
September 26, 2006
Contents
@ -9,6 +9,7 @@ Contents
- In This Release
- Identifying Your Adapter
- Building and Installation
- Command Line Parameters
- Speed and Duplex Configuration
- Additional Configurations
@ -41,6 +42,9 @@ or later), lspci, and ifconfig to obtain the same information.
Instructions on updating ethtool can be found in the section "Additional
Configurations" later in this document.
NOTE: The Intel(R) 82562v 10/100 Network Connection only provides 10/100
support.
Identifying Your Adapter
========================
@ -57,22 +61,21 @@ networking link on the left to search for your adapter:
http://downloadfinder.intel.com/scripts-df/support_intel.asp
Command Line Parameters =======================
Command Line Parameters
=======================
If the driver is built as a module, the following optional parameters
are used by entering them on the command line with the modprobe or insmod
command using this syntax:
are used by entering them on the command line with the modprobe command
using this syntax:
modprobe e1000 [<option>=<VAL1>,<VAL2>,...]
insmod e1000 [<option>=<VAL1>,<VAL2>,...]
For example, with two PRO/1000 PCI adapters, entering:
insmod e1000 TxDescriptors=80,128
modprobe e1000 TxDescriptors=80,128
loads the e1000 driver with 80 TX descriptors for the first adapter and 128
TX descriptors for the second adapter.
loads the e1000 driver with 80 TX descriptors for the first adapter and
128 TX descriptors for the second adapter.
The default value for each parameter is generally the recommended setting,
unless otherwise noted.
@ -96,9 +99,9 @@ AutoNeg
Valid Range: 0x01-0x0F, 0x20-0x2F
Default Value: 0x2F
This parameter is a bit mask that specifies which speed and duplex
settings the board advertises. When this parameter is used, the Speed
and Duplex parameters must not be specified.
This parameter is a bit-mask that specifies the speed and duplex settings
advertised by the adapter. When this parameter is used, the Speed and
Duplex parameters must not be specified.
NOTE: Refer to the Speed and Duplex section of this readme for more
information on the AutoNeg parameter.
@ -110,14 +113,15 @@ Duplex
Valid Range: 0-2 (0=auto-negotiate, 1=half, 2=full)
Default Value: 0
Defines the direction in which data is allowed to flow. Can be either
one or two-directional. If both Duplex and the link partner are set to
auto-negotiate, the board auto-detects the correct duplex. If the link
partner is forced (either full or half), Duplex defaults to half-duplex.
This defines the direction in which data is allowed to flow. Can be
either one or two-directional. If both Duplex and the link partner are
set to auto-negotiate, the board auto-detects the correct duplex. If the
link partner is forced (either full or half), Duplex defaults to half-
duplex.
FlowControl
----------
-----------
Valid Range: 0-3 (0=none, 1=Rx only, 2=Tx only, 3=Rx&Tx)
Default Value: Reads flow control settings from the EEPROM
@ -127,14 +131,55 @@ to Ethernet PAUSE frames.
InterruptThrottleRate
---------------------
(not supported on Intel 82542, 82543 or 82544-based adapters)
Valid Range: 100-100000 (0=off, 1=dynamic)
Default Value: 8000
(not supported on Intel(R) 82542, 82543 or 82544-based adapters)
Valid Range: 0,1,3,100-100000 (0=off, 1=dynamic, 3=dynamic conservative)
Default Value: 3
This value represents the maximum number of interrupts per second the
controller generates. InterruptThrottleRate is another setting used in
interrupt moderation. Dynamic mode uses a heuristic algorithm to adjust
InterruptThrottleRate based on the current traffic load.
The driver can limit the amount of interrupts per second that the adapter
will generate for incoming packets. It does this by writing a value to the
adapter that is based on the maximum amount of interrupts that the adapter
will generate per second.
Setting InterruptThrottleRate to a value greater or equal to 100
will program the adapter to send out a maximum of that many interrupts
per second, even if more packets have come in. This reduces interrupt
load on the system and can lower CPU utilization under heavy load,
but will increase latency as packets are not processed as quickly.
The default behaviour of the driver previously assumed a static
InterruptThrottleRate value of 8000, providing a good fallback value for
all traffic types,but lacking in small packet performance and latency.
The hardware can handle many more small packets per second however, and
for this reason an adaptive interrupt moderation algorithm was implemented.
Since 7.3.x, the driver has two adaptive modes (setting 1 or 3) in which
it dynamically adjusts the InterruptThrottleRate value based on the traffic
that it receives. After determining the type of incoming traffic in the last
timeframe, it will adjust the InterruptThrottleRate to an appropriate value
for that traffic.
The algorithm classifies the incoming traffic every interval into
classes. Once the class is determined, the InterruptThrottleRate value is
adjusted to suit that traffic type the best. There are three classes defined:
"Bulk traffic", for large amounts of packets of normal size; "Low latency",
for small amounts of traffic and/or a significant percentage of small
packets; and "Lowest latency", for almost completely small packets or
minimal traffic.
In dynamic conservative mode, the InterruptThrottleRate value is set to 4000
for traffic that falls in class "Bulk traffic". If traffic falls in the "Low
latency" or "Lowest latency" class, the InterruptThrottleRate is increased
stepwise to 20000. This default mode is suitable for most applications.
For situations where low latency is vital such as cluster or
grid computing, the algorithm can reduce latency even more when
InterruptThrottleRate is set to mode 1. In this mode, which operates
the same as mode 3, the InterruptThrottleRate will be increased stepwise to
70000 for traffic in class "Lowest latency".
Setting InterruptThrottleRate to 0 turns off any interrupt moderation
and may improve small packet latency, but is generally not suitable
for bulk throughput traffic.
NOTE: InterruptThrottleRate takes precedence over the TxAbsIntDelay and
RxAbsIntDelay parameters. In other words, minimizing the receive
@ -142,7 +187,7 @@ NOTE: InterruptThrottleRate takes precedence over the TxAbsIntDelay and
generate more interrupts than what the Interrupt Throttle Rate
allows.
CAUTION: If you are using the Intel PRO/1000 CT Network Connection
CAUTION: If you are using the Intel(R) PRO/1000 CT Network Connection
(controller 82547), setting InterruptThrottleRate to a value
greater than 75,000, may hang (stop transmitting) adapters
under certain network conditions. If this occurs a NETDEV
@ -158,7 +203,7 @@ NOTE: When e1000 is loaded with default settings and multiple adapters
the overall throughput, we recommend that you load the driver as
follows:
insmod e1000.o InterruptThrottleRate=3000,3000,3000
modprobe e1000 InterruptThrottleRate=3000,3000,3000
This sets the InterruptThrottleRate to 3000 interrupts/sec for
the first, second, and third instances of the driver. The range
@ -168,16 +213,25 @@ NOTE: When e1000 is loaded with default settings and multiple adapters
RX_POLLING (NAPI) and default driver settings.
RxDescriptors
-------------
Valid Range: 80-256 for 82542 and 82543-based adapters
80-4096 for all other supported adapters
Default Value: 256
This value specifies the number of receive descriptors allocated by the
driver. Increasing this value allows the driver to buffer more incoming
packets. Each descriptor is 16 bytes. A receive buffer is also
allocated for each descriptor and is 2048.
This value specifies the number of receive buffer descriptors allocated
by the driver. Increasing this value allows the driver to buffer more
incoming packets, at the expense of increased system memory utilization.
Each descriptor is 16 bytes. A receive buffer is also allocated for each
descriptor and can be either 2048, 4096, 8192, or 16384 bytes, depending
on the MTU setting. The maximum MTU size is 16110.
NOTE: MTU designates the frame size. It only needs to be set for Jumbo
Frames. Depending on the available system resources, the request
for a higher number of receive descriptors may be denied. In this
case, use a lower number.
RxIntDelay
@ -304,7 +358,7 @@ auto-negotiation process. It should be used when you wish to control which
speed and duplex combinations are advertised during the auto-negotiation
process.
The parameter may be specified as either a decimal or hexidecimal value as
The parameter may be specified as either a decimal or hexadecimal value as
determined by the bitmap below.
Bit position 7 6 5 4 3 2 1 0
@ -337,7 +391,6 @@ Additional Configurations
Configuring the Driver on Different Distributions
-------------------------------------------------
Configuring a network driver to load properly when the system is started
is distribution dependent. Typically, the configuration process involves
adding an alias line to /etc/modules.conf or /etc/modprobe.conf as well
@ -346,11 +399,11 @@ Additional Configurations
To learn the proper way to configure a network device for your system,
refer to your distribution documentation. If during this process you are
asked for the driver or module name, the name for the Linux Base Driver
for the Intel PRO/1000 Family of Adapters is e1000.
for the Intel(R) PRO/1000 Family of Adapters is e1000.
As an example, if you install the e1000 driver for two PRO/1000 adapters
(eth0 and eth1) and set the speed and duplex to 10full and 100half, add
the following to modules.conf or modprobe.conf:
the following to modules.conf or or modprobe.conf:
alias eth0 e1000
alias eth1 e1000
@ -358,7 +411,6 @@ Additional Configurations
Viewing Link Messages
---------------------
Link messages will not be displayed to the console if the distribution is
restricting system messages. In order to see network driver link messages
on your console, set dmesg to eight by entering the following:
@ -369,11 +421,9 @@ Additional Configurations
Jumbo Frames
------------
The driver supports Jumbo Frames for all adapters except 82542 and
82573-based adapters. Jumbo Frames support is enabled by changing the
MTU to a value larger than the default of 1500. Use the ifconfig command
to increase the MTU size. For example:
Jumbo Frames support is enabled by changing the MTU to a value larger than
the default of 1500. Use the ifconfig command to increase the MTU size.
For example:
ifconfig eth<x> mtu 9000 up
@ -390,26 +440,49 @@ Additional Configurations
- To enable Jumbo Frames, increase the MTU size on the interface beyond
1500.
- The maximum MTU setting for Jumbo Frames is 16110. This value coincides
with the maximum Jumbo Frames size of 16128.
- Using Jumbo Frames at 10 or 100 Mbps may result in poor performance or
loss of link.
- Some Intel gigabit adapters that support Jumbo Frames have a frame size
limit of 9238 bytes, with a corresponding MTU size limit of 9216 bytes.
The adapters with this limitation are based on the Intel 82571EB and
82572EI controllers, which correspond to these product names:
Intel® PRO/1000 PT Dual Port Server Adapter
Intel® PRO/1000 PF Dual Port Server Adapter
Intel® PRO/1000 PT Server Adapter
Intel® PRO/1000 PT Desktop Adapter
Intel® PRO/1000 PF Server Adapter
The adapters with this limitation are based on the Intel(R) 82571EB,
82572EI, 82573L and 80003ES2LAN controller. These correspond to the
following product names:
Intel(R) PRO/1000 PT Server Adapter
Intel(R) PRO/1000 PT Desktop Adapter
Intel(R) PRO/1000 PT Network Connection
Intel(R) PRO/1000 PT Dual Port Server Adapter
Intel(R) PRO/1000 PT Dual Port Network Connection
Intel(R) PRO/1000 PF Server Adapter
Intel(R) PRO/1000 PF Network Connection
Intel(R) PRO/1000 PF Dual Port Server Adapter
Intel(R) PRO/1000 PB Server Connection
Intel(R) PRO/1000 PL Network Connection
Intel(R) PRO/1000 EB Network Connection with I/O Acceleration
Intel(R) PRO/1000 EB Backplane Connection with I/O Acceleration
Intel(R) PRO/1000 PT Quad Port Server Adapter
- The Intel PRO/1000 PM Network Connection does not support jumbo frames.
- Adapters based on the Intel(R) 82542 and 82573V/E controller do not
support Jumbo Frames. These correspond to the following product names:
Intel(R) PRO/1000 Gigabit Server Adapter
Intel(R) PRO/1000 PM Network Connection
- The following adapters do not support Jumbo Frames:
Intel(R) 82562V 10/100 Network Connection
Intel(R) 82566DM Gigabit Network Connection
Intel(R) 82566DC Gigabit Network Connection
Intel(R) 82566MM Gigabit Network Connection
Intel(R) 82566MC Gigabit Network Connection
Intel(R) 82562GT 10/100 Network Connection
Intel(R) 82562G 10/100 Network Connection
Ethtool
-------
The driver utilizes the ethtool interface for driver configuration and
diagnostics, as well as displaying statistical information. Ethtool
version 1.6 or later is required for this functionality.
@ -423,7 +496,6 @@ Additional Configurations
Enabling Wake on LAN* (WoL)
---------------------------
WoL is configured through the Ethtool* utility. Ethtool is included with
all versions of Red Hat after Red Hat 7.2. For other Linux distributions,
download and install Ethtool from the following website:
@ -436,9 +508,15 @@ Additional Configurations
For this driver version, in order to enable WoL, the e1000 driver must be
loaded when shutting down or rebooting the system.
Wake On LAN is only supported on port A for the following devices:
Intel(R) PRO/1000 PT Dual Port Network Connection
Intel(R) PRO/1000 PT Dual Port Server Connection
Intel(R) PRO/1000 PT Dual Port Server Adapter
Intel(R) PRO/1000 PF Dual Port Server Adapter
Intel(R) PRO/1000 PT Quad Port Server Adapter
NAPI
----
NAPI (Rx polling mode) is supported in the e1000 driver. NAPI is enabled
or disabled based on the configuration of the kernel. To override
the default, use the following compile-time flags.
@ -457,9 +535,15 @@ Additional Configurations
Known Issues
============
Dropped Receive Packets on Half-duplex 10/100 Networks
------------------------------------------------------
If you have an Intel PCI Express adapter running at 10mbps or 100mbps, half-
duplex, you may observe occasional dropped receive packets. There are no
workarounds for this problem in this network configuration. The network must
be updated to operate in full-duplex, and/or 1000mbps only.
Jumbo Frames System Requirement
-------------------------------
Memory allocation failures have been observed on Linux systems with 64 MB
of RAM or less that are running Jumbo Frames. If you are using Jumbo
Frames, your system may require more than the advertised minimum
@ -467,7 +551,6 @@ Known Issues
Performance Degradation with Jumbo Frames
-----------------------------------------
Degradation in throughput performance may be observed in some Jumbo frames
environments. If this is observed, increasing the application's socket
buffer size and/or increasing the /proc/sys/net/ipv4/tcp_*mem entry values
@ -475,15 +558,22 @@ Known Issues
/usr/src/linux*/Documentation/
networking/ip-sysctl.txt for more details.
Jumbo frames on Foundry BigIron 8000 switch
Jumbo Frames on Foundry BigIron 8000 switch
-------------------------------------------
There is a known issue using Jumbo frames when connected to a Foundry
BigIron 8000 switch. This is a 3rd party limitation. If you experience
loss of packets, lower the MTU size.
Allocating Rx Buffers when Using Jumbo Frames
---------------------------------------------
Allocating Rx buffers when using Jumbo Frames on 2.6.x kernels may fail if
the available memory is heavily fragmented. This issue may be seen with PCI-X
adapters or with packet split disabled. This can be reduced or eliminated
by changing the amount of available memory for receive buffer allocation, by
increasing /proc/sys/vm/min_free_kbytes.
Multiple Interfaces on Same Ethernet Broadcast Network
------------------------------------------------------
Due to the default ARP behavior on Linux, it is not possible to have
one system on two IP networks in the same Ethernet broadcast domain
(non-partitioned switch) behave as expected. All Ethernet interfaces
@ -508,7 +598,6 @@ Known Issues
82541/82547 can't link or are slow to link with some link partners
-----------------------------------------------------------------
There is a known compatibility issue with 82541/82547 and some
low-end switches where the link will not be established, or will
be slow to establish. In particular, these switches are known to
@ -521,7 +610,7 @@ Known Issues
of the PHY's master/slave setting. Forcing master or forcing slave
mode will improve time-to-link.
# make EXTRA_CFLAGS=-DE1000_MASTER_SLAVE=<n>
# make CFLAGS_EXTRA=-DE1000_MASTER_SLAVE=<n>
Where <n> is:
@ -532,7 +621,6 @@ Known Issues
Disable rx flow control with ethtool
------------------------------------
In order to disable receive flow control using ethtool, you must turn
off auto-negotiation on the same command line.
@ -540,6 +628,13 @@ Known Issues
ethtool -A eth? autoneg off rx off
Unplugging network cable while ethtool -p is running
----------------------------------------------------
In kernel versions 2.5.50 and later (including 2.6 kernel), unplugging
the network cable while ethtool -p is running will cause the system to
become unresponsive to keyboard commands, except for control-alt-delete.
Restarting the system appears to be the only remedy.
Support
=======
@ -554,18 +649,4 @@ For general information, go to the Intel support website at:
If an issue is identified with the released source code on the supported
kernel with a supported adapter, email the specific information related
to the issue to e1000-devel@lists.sourceforge.net
License
=======
This software program is released under the terms of a license agreement
between you ('Licensee') and Intel. Do not use or load this software or any
associated materials (collectively, the 'Software') until you have carefully
read the full terms and conditions of the file COPYING located in this software
package. By loading or using the Software, you agree to the terms of this
Agreement. If you do not agree with the terms of this Agreement, do not
install or use the Software.
* Other names and brands may be claimed as the property of others.
to the issue to e1000-devel@lists.sf.net

View File

@ -0,0 +1,3 @@
A wiki document on how to use Generic Netlink can be found here:
* http://linux-net.osdl.org/index.php/Generic_Netlink_HOWTO

View File

@ -101,6 +101,11 @@ inet_peer_gc_maxtime - INTEGER
TCP variables:
somaxconn - INTEGER
Limit of socket listen() backlog, known in userspace as SOMAXCONN.
Defaults to 128. See also tcp_max_syn_backlog for additional tuning
for TCP sockets.
tcp_abc - INTEGER
Controls Appropriate Byte Count (ABC) defined in RFC3465.
ABC is a way of increasing congestion window (cwnd) more slowly
@ -112,15 +117,68 @@ tcp_abc - INTEGER
of two segments to compensate for delayed acknowledgments.
Default: 0 (off)
tcp_syn_retries - INTEGER
Number of times initial SYNs for an active TCP connection attempt
will be retransmitted. Should not be higher than 255. Default value
is 5, which corresponds to ~180seconds.
tcp_abort_on_overflow - BOOLEAN
If listening service is too slow to accept new connections,
reset them. Default state is FALSE. It means that if overflow
occurred due to a burst, connection will recover. Enable this
option _only_ if you are really sure that listening daemon
cannot be tuned to accept connections faster. Enabling this
option can harm clients of your server.
tcp_synack_retries - INTEGER
Number of times SYNACKs for a passive TCP connection attempt will
be retransmitted. Should not be higher than 255. Default value
is 5, which corresponds to ~180seconds.
tcp_adv_win_scale - INTEGER
Count buffering overhead as bytes/2^tcp_adv_win_scale
(if tcp_adv_win_scale > 0) or bytes-bytes/2^(-tcp_adv_win_scale),
if it is <= 0.
Default: 2
tcp_allowed_congestion_control - STRING
Show/set the congestion control choices available to non-privileged
processes. The list is a subset of those listed in
tcp_available_congestion_control.
Default is "reno" and the default setting (tcp_congestion_control).
tcp_app_win - INTEGER
Reserve max(window/2^tcp_app_win, mss) of window for application
buffer. Value 0 is special, it means that nothing is reserved.
Default: 31
tcp_available_congestion_control - STRING
Shows the available congestion control choices that are registered.
More congestion control algorithms may be available as modules,
but not loaded.
tcp_congestion_control - STRING
Set the congestion control algorithm to be used for new
connections. The algorithm "reno" is always available, but
additional choices may be available based on kernel configuration.
Default is set as part of kernel configuration.
tcp_dsack - BOOLEAN
Allows TCP to send "duplicate" SACKs.
tcp_ecn - BOOLEAN
Enable Explicit Congestion Notification in TCP.
tcp_fack - BOOLEAN
Enable FACK congestion avoidance and fast retransmission.
The value is not used, if tcp_sack is not enabled.
tcp_fin_timeout - INTEGER
Time to hold socket in state FIN-WAIT-2, if it was closed
by our side. Peer can be broken and never close its side,
or even died unexpectedly. Default value is 60sec.
Usual value used in 2.2 was 180 seconds, you may restore
it, but remember that if your machine is even underloaded WEB server,
you risk to overflow memory with kilotons of dead sockets,
FIN-WAIT-2 sockets are less dangerous than FIN-WAIT-1,
because they eat maximum 1.5K of memory, but they tend
to live longer. Cf. tcp_max_orphans.
tcp_frto - BOOLEAN
Enables F-RTO, an enhanced recovery algorithm for TCP retransmission
timeouts. It is particularly beneficial in wireless environments
where packet loss is typically due to random radio interference
rather than intermediate router congestion.
tcp_keepalive_time - INTEGER
How often TCP sends out keepalive messages when keepalive is enabled.
@ -136,54 +194,13 @@ tcp_keepalive_intvl - INTEGER
after probes started. Default value: 75sec i.e. connection
will be aborted after ~11 minutes of retries.
tcp_retries1 - INTEGER
How many times to retry before deciding that something is wrong
and it is necessary to report this suspicion to network layer.
Minimal RFC value is 3, it is default, which corresponds
to ~3sec-8min depending on RTO.
tcp_retries2 - INTEGER
How may times to retry before killing alive TCP connection.
RFC1122 says that the limit should be longer than 100 sec.
It is too small number. Default value 15 corresponds to ~13-30min
depending on RTO.
tcp_orphan_retries - INTEGER
How may times to retry before killing TCP connection, closed
by our side. Default value 7 corresponds to ~50sec-16min
depending on RTO. If you machine is loaded WEB server,
you should think about lowering this value, such sockets
may consume significant resources. Cf. tcp_max_orphans.
tcp_fin_timeout - INTEGER
Time to hold socket in state FIN-WAIT-2, if it was closed
by our side. Peer can be broken and never close its side,
or even died unexpectedly. Default value is 60sec.
Usual value used in 2.2 was 180 seconds, you may restore
it, but remember that if your machine is even underloaded WEB server,
you risk to overflow memory with kilotons of dead sockets,
FIN-WAIT-2 sockets are less dangerous than FIN-WAIT-1,
because they eat maximum 1.5K of memory, but they tend
to live longer. Cf. tcp_max_orphans.
tcp_max_tw_buckets - INTEGER
Maximal number of timewait sockets held by system simultaneously.
If this number is exceeded time-wait socket is immediately destroyed
and warning is printed. This limit exists only to prevent
simple DoS attacks, you _must_ not lower the limit artificially,
but rather increase it (probably, after increasing installed memory),
if network conditions require more than default value.
tcp_tw_recycle - BOOLEAN
Enable fast recycling TIME-WAIT sockets. Default value is 0.
It should not be changed without advice/request of technical
experts.
tcp_tw_reuse - BOOLEAN
Allow to reuse TIME-WAIT sockets for new connections when it is
safe from protocol viewpoint. Default value is 0.
It should not be changed without advice/request of technical
experts.
tcp_low_latency - BOOLEAN
If set, the TCP stack makes decisions that prefer lower
latency as opposed to higher throughput. By default, this
option is not set meaning that higher throughput is preferred.
An example of an application where this default should be
changed would be a Beowulf compute cluster.
Default: 0
tcp_max_orphans - INTEGER
Maximal number of TCP sockets not attached to any user file handle,
@ -197,13 +214,106 @@ tcp_max_orphans - INTEGER
more aggressively. Let me to remind again: each orphan eats
up to ~64K of unswappable memory.
tcp_abort_on_overflow - BOOLEAN
If listening service is too slow to accept new connections,
reset them. Default state is FALSE. It means that if overflow
occurred due to a burst, connection will recover. Enable this
option _only_ if you are really sure that listening daemon
cannot be tuned to accept connections faster. Enabling this
option can harm clients of your server.
tcp_max_syn_backlog - INTEGER
Maximal number of remembered connection requests, which are
still did not receive an acknowledgment from connecting client.
Default value is 1024 for systems with more than 128Mb of memory,
and 128 for low memory machines. If server suffers of overload,
try to increase this number.
tcp_max_tw_buckets - INTEGER
Maximal number of timewait sockets held by system simultaneously.
If this number is exceeded time-wait socket is immediately destroyed
and warning is printed. This limit exists only to prevent
simple DoS attacks, you _must_ not lower the limit artificially,
but rather increase it (probably, after increasing installed memory),
if network conditions require more than default value.
tcp_mem - vector of 3 INTEGERs: min, pressure, max
min: below this number of pages TCP is not bothered about its
memory appetite.
pressure: when amount of memory allocated by TCP exceeds this number
of pages, TCP moderates its memory consumption and enters memory
pressure mode, which is exited when memory consumption falls
under "min".
max: number of pages allowed for queueing by all TCP sockets.
Defaults are calculated at boot time from amount of available
memory.
tcp_orphan_retries - INTEGER
How may times to retry before killing TCP connection, closed
by our side. Default value 7 corresponds to ~50sec-16min
depending on RTO. If you machine is loaded WEB server,
you should think about lowering this value, such sockets
may consume significant resources. Cf. tcp_max_orphans.
tcp_reordering - INTEGER
Maximal reordering of packets in a TCP stream.
Default: 3
tcp_retrans_collapse - BOOLEAN
Bug-to-bug compatibility with some broken printers.
On retransmit try to send bigger packets to work around bugs in
certain TCP stacks.
tcp_retries1 - INTEGER
How many times to retry before deciding that something is wrong
and it is necessary to report this suspicion to network layer.
Minimal RFC value is 3, it is default, which corresponds
to ~3sec-8min depending on RTO.
tcp_retries2 - INTEGER
How may times to retry before killing alive TCP connection.
RFC1122 says that the limit should be longer than 100 sec.
It is too small number. Default value 15 corresponds to ~13-30min
depending on RTO.
tcp_rfc1337 - BOOLEAN
If set, the TCP stack behaves conforming to RFC1337. If unset,
we are not conforming to RFC, but prevent TCP TIME_WAIT
assassination.
Default: 0
tcp_rmem - vector of 3 INTEGERs: min, default, max
min: Minimal size of receive buffer used by TCP sockets.
It is guaranteed to each TCP socket, even under moderate memory
pressure.
Default: 8K
default: default size of receive buffer used by TCP sockets.
This value overrides net.core.rmem_default used by other protocols.
Default: 87380 bytes. This value results in window of 65535 with
default setting of tcp_adv_win_scale and tcp_app_win:0 and a bit
less for default tcp_app_win. See below about these variables.
max: maximal size of receive buffer allowed for automatically
selected receiver buffers for TCP socket. This value does not override
net.core.rmem_max, "static" selection via SO_RCVBUF does not use this.
Default: 87380*2 bytes.
tcp_sack - BOOLEAN
Enable select acknowledgments (SACKS).
tcp_slow_start_after_idle - BOOLEAN
If set, provide RFC2861 behavior and time out the congestion
window after an idle period. An idle period is defined at
the current RTO. If unset, the congestion window will not
be timed out after an idle period.
Default: 1
tcp_stdurg - BOOLEAN
Use the Host requirements interpretation of the TCP urg pointer field.
Most hosts use the older BSD interpretation, so if you turn this on
Linux might not communicate correctly with them.
Default: FALSE
tcp_synack_retries - INTEGER
Number of times SYNACKs for a passive TCP connection attempt will
be retransmitted. Should not be higher than 255. Default value
is 5, which corresponds to ~180seconds.
tcp_syncookies - BOOLEAN
Only valid when the kernel was compiled with CONFIG_SYNCOOKIES
@ -226,46 +336,34 @@ tcp_syncookies - BOOLEAN
synflood warnings in logs not being really flooded, your server
is seriously misconfigured.
tcp_stdurg - BOOLEAN
Use the Host requirements interpretation of the TCP urg pointer field.
Most hosts use the older BSD interpretation, so if you turn this on
Linux might not communicate correctly with them.
Default: FALSE
tcp_max_syn_backlog - INTEGER
Maximal number of remembered connection requests, which are
still did not receive an acknowledgment from connecting client.
Default value is 1024 for systems with more than 128Mb of memory,
and 128 for low memory machines. If server suffers of overload,
try to increase this number.
tcp_window_scaling - BOOLEAN
Enable window scaling as defined in RFC1323.
tcp_syn_retries - INTEGER
Number of times initial SYNs for an active TCP connection attempt
will be retransmitted. Should not be higher than 255. Default value
is 5, which corresponds to ~180seconds.
tcp_timestamps - BOOLEAN
Enable timestamps as defined in RFC1323.
tcp_sack - BOOLEAN
Enable select acknowledgments (SACKS).
tcp_fack - BOOLEAN
Enable FACK congestion avoidance and fast retransmission.
The value is not used, if tcp_sack is not enabled.
tcp_dsack - BOOLEAN
Allows TCP to send "duplicate" SACKs.
tcp_ecn - BOOLEAN
Enable Explicit Congestion Notification in TCP.
tcp_reordering - INTEGER
Maximal reordering of packets in a TCP stream.
tcp_tso_win_divisor - INTEGER
This allows control over what percentage of the congestion window
can be consumed by a single TSO frame.
The setting of this parameter is a choice between burstiness and
building larger TSO frames.
Default: 3
tcp_retrans_collapse - BOOLEAN
Bug-to-bug compatibility with some broken printers.
On retransmit try to send bigger packets to work around bugs in
certain TCP stacks.
tcp_tw_recycle - BOOLEAN
Enable fast recycling TIME-WAIT sockets. Default value is 0.
It should not be changed without advice/request of technical
experts.
tcp_tw_reuse - BOOLEAN
Allow to reuse TIME-WAIT sockets for new connections when it is
safe from protocol viewpoint. Default value is 0.
It should not be changed without advice/request of technical
experts.
tcp_window_scaling - BOOLEAN
Enable window scaling as defined in RFC1323.
tcp_wmem - vector of 3 INTEGERs: min, default, max
min: Amount of memory reserved for send buffers for TCP socket.
@ -282,85 +380,6 @@ tcp_wmem - vector of 3 INTEGERs: min, default, max
net.core.wmem_max, "static" selection via SO_SNDBUF does not use this.
Default: 128K
tcp_rmem - vector of 3 INTEGERs: min, default, max
min: Minimal size of receive buffer used by TCP sockets.
It is guaranteed to each TCP socket, even under moderate memory
pressure.
Default: 8K
default: default size of receive buffer used by TCP sockets.
This value overrides net.core.rmem_default used by other protocols.
Default: 87380 bytes. This value results in window of 65535 with
default setting of tcp_adv_win_scale and tcp_app_win:0 and a bit
less for default tcp_app_win. See below about these variables.
max: maximal size of receive buffer allowed for automatically
selected receiver buffers for TCP socket. This value does not override
net.core.rmem_max, "static" selection via SO_RCVBUF does not use this.
Default: 87380*2 bytes.
tcp_mem - vector of 3 INTEGERs: min, pressure, max
min: below this number of pages TCP is not bothered about its
memory appetite.
pressure: when amount of memory allocated by TCP exceeds this number
of pages, TCP moderates its memory consumption and enters memory
pressure mode, which is exited when memory consumption falls
under "min".
max: number of pages allowed for queueing by all TCP sockets.
Defaults are calculated at boot time from amount of available
memory.
tcp_app_win - INTEGER
Reserve max(window/2^tcp_app_win, mss) of window for application
buffer. Value 0 is special, it means that nothing is reserved.
Default: 31
tcp_adv_win_scale - INTEGER
Count buffering overhead as bytes/2^tcp_adv_win_scale
(if tcp_adv_win_scale > 0) or bytes-bytes/2^(-tcp_adv_win_scale),
if it is <= 0.
Default: 2
tcp_rfc1337 - BOOLEAN
If set, the TCP stack behaves conforming to RFC1337. If unset,
we are not conforming to RFC, but prevent TCP TIME_WAIT
assassination.
Default: 0
tcp_low_latency - BOOLEAN
If set, the TCP stack makes decisions that prefer lower
latency as opposed to higher throughput. By default, this
option is not set meaning that higher throughput is preferred.
An example of an application where this default should be
changed would be a Beowulf compute cluster.
Default: 0
tcp_tso_win_divisor - INTEGER
This allows control over what percentage of the congestion window
can be consumed by a single TSO frame.
The setting of this parameter is a choice between burstiness and
building larger TSO frames.
Default: 3
tcp_frto - BOOLEAN
Enables F-RTO, an enhanced recovery algorithm for TCP retransmission
timeouts. It is particularly beneficial in wireless environments
where packet loss is typically due to random radio interference
rather than intermediate router congestion.
tcp_congestion_control - STRING
Set the congestion control algorithm to be used for new
connections. The algorithm "reno" is always available, but
additional choices may be available based on kernel configuration.
somaxconn - INTEGER
Limit of socket listen() backlog, known in userspace as SOMAXCONN.
Defaults to 128. See also tcp_max_syn_backlog for additional tuning
for TCP sockets.
tcp_workaround_signed_windows - BOOLEAN
If set, assume no receipt of a window scaling option means the
remote TCP is broken and treats the window as a signed quantity.
@ -368,13 +387,6 @@ tcp_workaround_signed_windows - BOOLEAN
not receive a window scaling option from them.
Default: 0
tcp_slow_start_after_idle - BOOLEAN
If set, provide RFC2861 behavior and time out the congestion
window after an idle period. An idle period is defined at
the current RTO. If unset, the congestion window will not
be timed out after an idle period.
Default: 1
CIPSOv4 Variables:
cipso_cache_enable - BOOLEAN
@ -974,4 +986,3 @@ no_cong_thresh FIXME
slot_timeout FIXME
warn_noreply_time FIXME
$Id: ip-sysctl.txt,v 1.20 2001/12/13 09:00:18 davem Exp $

View File

@ -81,7 +81,7 @@ Installation
1M. The RAM size decides the number of buffers and buffer size. The default
size and number of buffers are set as following:
Totol Rx RAM Tx RAM Rx Buf Tx Buf Rx buf Tx buf
Total Rx RAM Tx RAM Rx Buf Tx Buf Rx buf Tx buf
RAM size size size size size cnt cnt
-------- ------ ------ ------ ------ ------ ------
128K 64K 64K 10K 10K 6 6

View File

@ -284,7 +284,7 @@ the necessary memory, so normally limits can be reached.
-------------------
If you check the source code you will see that what I draw here as a frame
is not only the link level frame. At the begining of each frame there is a
is not only the link level frame. At the beginning of each frame there is a
header called struct tpacket_hdr used in PACKET_MMAP to hold link level's frame
meta information like timestamp. So what we draw here a frame it's really
the following (from include/linux/if_packet.h):

View File

@ -1,7 +1,7 @@
-------
PHY Abstraction Layer
(Updated 2005-07-21)
(Updated 2006-11-30)
Purpose
@ -97,11 +97,12 @@ Letting the PHY Abstraction Layer do Everything
Next, you need to know the device name of the PHY connected to this device.
The name will look something like, "phy0:0", where the first number is the
bus id, and the second is the PHY's address on that bus.
bus id, and the second is the PHY's address on that bus. Typically,
the bus is responsible for making its ID unique.
Now, to connect, just call this function:
phydev = phy_connect(dev, phy_name, &adjust_link, flags);
phydev = phy_connect(dev, phy_name, &adjust_link, flags, interface);
phydev is a pointer to the phy_device structure which represents the PHY. If
phy_connect is successful, it will return the pointer. dev, here, is the
@ -115,6 +116,10 @@ Letting the PHY Abstraction Layer do Everything
This is useful if the system has put hardware restrictions on
the PHY/controller, of which the PHY needs to be aware.
interface is a u32 which specifies the connection type used
between the controller and the PHY. Examples are GMII, MII,
RGMII, and SGMII. For a full list, see include/linux/phy.h
Now just make sure that phydev->supported and phydev->advertising have any
values pruned from them which don't make sense for your controller (a 10/100
controller may be connected to a gigabit capable PHY, so you would need to
@ -191,7 +196,7 @@ Doing it all yourself
start, or disables then frees them for stop.
struct phy_device * phy_attach(struct net_device *dev, const char *phy_id,
u32 flags);
u32 flags, phy_interface_t interface);
Attaches a network device to a particular PHY, binding the PHY to a generic
driver if none was found during bus initialization. Passes in

View File

@ -63,8 +63,8 @@ Current:
Result: OK: 13101142(c12220741+d880401) usec, 10000000 (60byte,0frags)
763292pps 390Mb/sec (390805504bps) errors: 39664
Confguring threads and devices
==============================
Configuring threads and devices
================================
This is done via the /proc interface easiest done via pgset in the scripts
Examples:
@ -116,7 +116,7 @@ Examples:
there must be no spaces between the
arguments. Leading zeros are required.
Do not set the bottom of stack bit,
thats done automatically. If you do
that's done automatically. If you do
set the bottom of stack bit, that
indicates that you want to randomly
generate that address and the flag

View File

@ -25,7 +25,7 @@ up into 3 parts because of the length of the line):
1000 0 54165785 4 cd1e6040 25 4 27 3 -1
| | | | | | | | | |--> slow start size threshold,
| | | | | | | | | or -1 if the treshold
| | | | | | | | | or -1 if the threshold
| | | | | | | | | is >= 0xFFFF
| | | | | | | | |----> sending congestion window
| | | | | | | |-------> (ack.quick<<1)|ack.pingpong

View File

@ -346,7 +346,7 @@ Possible modes:
depending on the load of the system. If the driver detects that the
system load is too high, the driver tries to shield the system against
too much network load by enabling interrupt moderation. If - at a later
time - the CPU utilizaton decreases again (or if the network load is
time - the CPU utilization decreases again (or if the network load is
negligible) the interrupt moderation will automatically be disabled.
Interrupt moderation should be used when the driver has to handle one or more

View File

@ -126,7 +126,7 @@ comx0/boardnum - board number of the SliceCom in the PC (using the 'natural'
Though the options below are to be set on a single interface, they apply to the
whole board. The restriction, to use them on 'UP' interfaces, is because the
command sequence below could lead to unpredicable results.
command sequence below could lead to unpredictable results.
# echo 0 >boardnum
# echo internal >clock_source

View File

@ -0,0 +1,281 @@
===========================================================================
The UDP-Lite protocol (RFC 3828)
===========================================================================
UDP-Lite is a Standards-Track IETF transport protocol whose characteristic
is a variable-length checksum. This has advantages for transport of multimedia
(video, VoIP) over wireless networks, as partly damaged packets can still be
fed into the codec instead of being discarded due to a failed checksum test.
This file briefly describes the existing kernel support and the socket API.
For in-depth information, you can consult:
o The UDP-Lite Homepage: http://www.erg.abdn.ac.uk/users/gerrit/udp-lite/
Fom here you can also download some example application source code.
o The UDP-Lite HOWTO on
http://www.erg.abdn.ac.uk/users/gerrit/udp-lite/files/UDP-Lite-HOWTO.txt
o The Wireshark UDP-Lite WiKi (with capture files):
http://wiki.wireshark.org/Lightweight_User_Datagram_Protocol
o The Protocol Spec, RFC 3828, http://www.ietf.org/rfc/rfc3828.txt
I) APPLICATIONS
Several applications have been ported successfully to UDP-Lite. Ethereal
(now called wireshark) has UDP-Litev4/v6 support by default. The tarball on
http://www.erg.abdn.ac.uk/users/gerrit/udp-lite/files/udplite_linux.tar.gz
has source code for several v4/v6 client-server and network testing examples.
Porting applications to UDP-Lite is straightforward: only socket level and
IPPROTO need to be changed; senders additionally set the checksum coverage
length (default = header length = 8). Details are in the next section.
II) PROGRAMMING API
UDP-Lite provides a connectionless, unreliable datagram service and hence
uses the same socket type as UDP. In fact, porting from UDP to UDP-Lite is
very easy: simply add `IPPROTO_UDPLITE' as the last argument of the socket(2)
call so that the statement looks like:
s = socket(PF_INET, SOCK_DGRAM, IPPROTO_UDPLITE);
or, respectively,
s = socket(PF_INET6, SOCK_DGRAM, IPPROTO_UDPLITE);
With just the above change you are able to run UDP-Lite services or connect
to UDP-Lite servers. The kernel will assume that you are not interested in
using partial checksum coverage and so emulate UDP mode (full coverage).
To make use of the partial checksum coverage facilities requires setting a
single socket option, which takes an integer specifying the coverage length:
* Sender checksum coverage: UDPLITE_SEND_CSCOV
For example,
int val = 20;
setsockopt(s, SOL_UDPLITE, UDPLITE_SEND_CSCOV, &val, sizeof(int));
sets the checksum coverage length to 20 bytes (12b data + 8b header).
Of each packet only the first 20 bytes (plus the pseudo-header) will be
checksummed. This is useful for RTP applications which have a 12-byte
base header.
* Receiver checksum coverage: UDPLITE_RECV_CSCOV
This option is the receiver-side analogue. It is truly optional, i.e. not
required to enable traffic with partial checksum coverage. Its function is
that of a traffic filter: when enabled, it instructs the kernel to drop
all packets which have a coverage _less_ than this value. For example, if
RTP and UDP headers are to be protected, a receiver can enforce that only
packets with a minimum coverage of 20 are admitted:
int min = 20;
setsockopt(s, SOL_UDPLITE, UDPLITE_RECV_CSCOV, &min, sizeof(int));
The calls to getsockopt(2) are analogous. Being an extension and not a stand-
alone protocol, all socket options known from UDP can be used in exactly the
same manner as before, e.g. UDP_CORK or UDP_ENCAP.
A detailed discussion of UDP-Lite checksum coverage options is in section IV.
III) HEADER FILES
The socket API requires support through header files in /usr/include:
* /usr/include/netinet/in.h
to define IPPROTO_UDPLITE
* /usr/include/netinet/udplite.h
for UDP-Lite header fields and protocol constants
For testing purposes, the following can serve as a `mini' header file:
#define IPPROTO_UDPLITE 136
#define SOL_UDPLITE 136
#define UDPLITE_SEND_CSCOV 10
#define UDPLITE_RECV_CSCOV 11
Ready-made header files for various distros are in the UDP-Lite tarball.
IV) KERNEL BEHAVIOUR WITH REGARD TO THE VARIOUS SOCKET OPTIONS
To enable debugging messages, the log level need to be set to 8, as most
messages use the KERN_DEBUG level (7).
1) Sender Socket Options
If the sender specifies a value of 0 as coverage length, the module
assumes full coverage, transmits a packet with coverage length of 0
and according checksum. If the sender specifies a coverage < 8 and
different from 0, the kernel assumes 8 as default value. Finally,
if the specified coverage length exceeds the packet length, the packet
length is used instead as coverage length.
2) Receiver Socket Options
The receiver specifies the minimum value of the coverage length it
is willing to accept. A value of 0 here indicates that the receiver
always wants the whole of the packet covered. In this case, all
partially covered packets are dropped and an error is logged.
It is not possible to specify illegal values (<0 and <8); in these
cases the default of 8 is assumed.
All packets arriving with a coverage value less than the specified
threshold are discarded, these events are also logged.
3) Disabling the Checksum Computation
On both sender and receiver, checksumming will always be performed
and can not be disabled using SO_NO_CHECK. Thus
setsockopt(sockfd, SOL_SOCKET, SO_NO_CHECK, ... );
will always will be ignored, while the value of
getsockopt(sockfd, SOL_SOCKET, SO_NO_CHECK, &value, ...);
is meaningless (as in TCP). Packets with a zero checksum field are
illegal (cf. RFC 3828, sec. 3.1) will be silently discarded.
4) Fragmentation
The checksum computation respects both buffersize and MTU. The size
of UDP-Lite packets is determined by the size of the send buffer. The
minimum size of the send buffer is 2048 (defined as SOCK_MIN_SNDBUF
in include/net/sock.h), the default value is configurable as
net.core.wmem_default or via setting the SO_SNDBUF socket(7)
option. The maximum upper bound for the send buffer is determined
by net.core.wmem_max.
Given a payload size larger than the send buffer size, UDP-Lite will
split the payload into several individual packets, filling up the
send buffer size in each case.
The precise value also depends on the interface MTU. The interface MTU,
in turn, may trigger IP fragmentation. In this case, the generated
UDP-Lite packet is split into several IP packets, of which only the
first one contains the L4 header.
The send buffer size has implications on the checksum coverage length.
Consider the following example:
Payload: 1536 bytes Send Buffer: 1024 bytes
MTU: 1500 bytes Coverage Length: 856 bytes
UDP-Lite will ship the 1536 bytes in two separate packets:
Packet 1: 1024 payload + 8 byte header + 20 byte IP header = 1052 bytes
Packet 2: 512 payload + 8 byte header + 20 byte IP header = 540 bytes
The coverage packet covers the UDP-Lite header and 848 bytes of the
payload in the first packet, the second packet is fully covered. Note
that for the second packet, the coverage length exceeds the packet
length. The kernel always re-adjusts the coverage length to the packet
length in such cases.
As an example of what happens when one UDP-Lite packet is split into
several tiny fragments, consider the following example.
Payload: 1024 bytes Send buffer size: 1024 bytes
MTU: 300 bytes Coverage length: 575 bytes
+-+-----------+--------------+--------------+--------------+
|8| 272 | 280 | 280 | 280 |
+-+-----------+--------------+--------------+--------------+
280 560 840 1032
^
*****checksum coverage*************
The UDP-Lite module generates one 1032 byte packet (1024 + 8 byte
header). According to the interface MTU, these are split into 4 IP
packets (280 byte IP payload + 20 byte IP header). The kernel module
sums the contents of the entire first two packets, plus 15 bytes of
the last packet before releasing the fragments to the IP module.
To see the analogous case for IPv6 fragmentation, consider a link
MTU of 1280 bytes and a write buffer of 3356 bytes. If the checksum
coverage is less than 1232 bytes (MTU minus IPv6/fragment header
lengths), only the first fragment needs to be considered. When using
larger checksum coverage lengths, each eligible fragment needs to be
checksummed. Suppose we have a checksum coverage of 3062. The buffer
of 3356 bytes will be split into the following fragments:
Fragment 1: 1280 bytes carrying 1232 bytes of UDP-Lite data
Fragment 2: 1280 bytes carrying 1232 bytes of UDP-Lite data
Fragment 3: 948 bytes carrying 900 bytes of UDP-Lite data
The first two fragments have to be checksummed in full, of the last
fragment only 598 (= 3062 - 2*1232) bytes are checksummed.
While it is important that such cases are dealt with correctly, they
are (annoyingly) rare: UDP-Lite is designed for optimising multimedia
performance over wireless (or generally noisy) links and thus smaller
coverage lenghts are likely to be expected.
V) UDP-LITE RUNTIME STATISTICS AND THEIR MEANING
Exceptional and error conditions are logged to syslog at the KERN_DEBUG
level. Live statistics about UDP-Lite are available in /proc/net/snmp
and can (with newer versions of netstat) be viewed using
netstat -svu
This displays UDP-Lite statistics variables, whose meaning is as follows.
InDatagrams: Total number of received datagrams.
NoPorts: Number of packets received to an unknown port.
These cases are counted separately (not as InErrors).
InErrors: Number of erroneous UDP-Lite packets. Errors include:
* internal socket queue receive errors
* packet too short (less than 8 bytes or stated
coverage length exceeds received length)
* xfrm4_policy_check() returned with error
* application has specified larger min. coverage
length than that of incoming packet
* checksum coverage violated
* bad checksum
OutDatagrams: Total number of sent datagrams.
These statistics derive from the UDP MIB (RFC 2013).
VI) IPTABLES
There is packet match support for UDP-Lite as well as support for the LOG target.
If you copy and paste the following line into /etc/protcols,
udplite 136 UDP-Lite # UDP-Lite [RFC 3828]
then
iptables -A INPUT -p udplite -j LOG
will produce logging output to syslog. Dropping and rejecting packets also works.
VII) MAINTAINER ADDRESS
The UDP-Lite patch was developed at
University of Aberdeen
Electronics Research Group
Department of Engineering
Fraser Noble Building
Aberdeen AB24 3UE; UK
The current maintainer is Gerrit Renker, <gerrit@erg.abdn.ac.uk>. Initial
code was developed by William Stanislaus, <william@erg.abdn.ac.uk>.

View File

@ -412,7 +412,7 @@ beta-2.1.4 Jul 2000 o Dynamic interface configuration:
beta3-2.1.4 Jul 2000 o X25 M_BIT Problem fix.
o Added the Multi-Port PPP
Updated utilites for the Multi-Port PPP.
Updated utilities for the Multi-Port PPP.
2.1.4 Aut 2000
o In X25API:
@ -444,13 +444,13 @@ beta1-2.1.5 Nov 15 2000
o Cpipemon
- Added set FT1 commands to the cpipemon. Thus CSU/DSU
configuraiton can be performed using cpipemon.
configuration can be performed using cpipemon.
All systems that cannot run cfgft1 GUI utility should
use cpipemon to configure the on board CSU/DSU.
o Keyboard Led Monitor/Debugger
- A new utilty /usr/sbin/wpkbdmon uses keyboard leds
- A new utility /usr/sbin/wpkbdmon uses keyboard leds
to convey operational statistic information of the
Sangoma WANPIPE cards.
NUM_LOCK = Line State (On=connected, Off=disconnected)
@ -464,7 +464,7 @@ beta1-2.1.5 Nov 15 2000
- Appropriate number of devices are dynamically loaded
based on the number of Sangoma cards found.
Note: The kernel configuraiton option
Note: The kernel configuration option
CONFIG_WANPIPE_CARDS has been taken out.
o Fixed the Frame Relay and Chdlc network interfaces so they are

View File

@ -47,10 +47,13 @@ aevent_id structure looks like:
struct xfrm_aevent_id {
struct xfrm_usersa_id sa_id;
xfrm_address_t saddr;
__u32 flags;
__u32 reqid;
};
xfrm_usersa_id in this message layout identifies the SA.
The unique SA is identified by the combination of xfrm_usersa_id,
reqid and saddr.
flags are used to indicate different things. The possible
flags are:

View File

@ -184,7 +184,7 @@ static const struct pnp_id pnp_dev_table[] = {
Please note that the character 'X' can be used as a wild card in the function
portion (last four characters).
ex:
/* Unkown PnP modems */
/* Unknown PnP modems */
{ "PNPCXXX", UNKNOWN_DEV },
Supported PnP card IDs can optionally be defined.

View File

@ -153,7 +153,7 @@ Description:
events, which is implicit if it doesn't even support it in the first
place).
Note that the PMC Register in the device's PM Capabilties has a bitmask
Note that the PMC Register in the device's PM Capabilities has a bitmask
of the states it supports generating PME# from. D3hot is bit 3 and
D3cold is bit 4. So, while a value of 4 as the state may not seem
semantically correct, it is.
@ -268,7 +268,7 @@ to wake the system up. (However, it is possible that a device may support
some non-standard way of generating a wake event on sleep.)
Bits 15:11 of the PMC (Power Mgmt Capabilities) Register in a device's
PM Capabilties describe what power states the device supports generating a
PM Capabilities describe what power states the device supports generating a
wake event from:
+------------------+

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@ -0,0 +1,56 @@
How to get s2ram working
~~~~~~~~~~~~~~~~~~~~~~~~
2006 Linus Torvalds
2006 Pavel Machek
1) Check suspend.sf.net, program s2ram there has long whitelist of
"known ok" machines, along with tricks to use on each one.
2) If that does not help, try reading tricks.txt and
video.txt. Perhaps problem is as simple as broken module, and
simple module unload can fix it.
3) You can use Linus' TRACE_RESUME infrastructure, described below.
Using TRACE_RESUME
~~~~~~~~~~~~~~~~~~
I've been working at making the machines I have able to STR, and almost
always it's a driver that is buggy. Thank God for the suspend/resume
debugging - the thing that Chuck tried to disable. That's often the _only_
way to debug these things, and it's actually pretty powerful (but
time-consuming - having to insert TRACE_RESUME() markers into the device
driver that doesn't resume and recompile and reboot).
Anyway, the way to debug this for people who are interested (have a
machine that doesn't boot) is:
- enable PM_DEBUG, and PM_TRACE
- use a script like this:
#!/bin/sh
sync
echo 1 > /sys/power/pm_trace
echo mem > /sys/power/state
to suspend
- if it doesn't come back up (which is usually the problem), reboot by
holding the power button down, and look at the dmesg output for things
like
Magic number: 4:156:725
hash matches drivers/base/power/resume.c:28
hash matches device 0000:01:00.0
which means that the last trace event was just before trying to resume
device 0000:01:00.0. Then figure out what driver is controlling that
device (lspci and /sys/devices/pci* is your friend), and see if you can
fix it, disable it, or trace into its resume function.
For example, the above happens to be the VGA device on my EVO, which I
used to run with "radeonfb" (it's an ATI Radeon mobility). It turns out
that "radeonfb" simply cannot resume that device - it tries to set the
PLL's, and it just _hangs_. Using the regular VGA console and letting X
resume it instead works fine.

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@ -62,7 +62,7 @@ setup via another operating system for it to use. Despite the
inconvenience, this method requires minimal work by the kernel, since
the firmware will also handle restoring memory contents on resume.
If the kernel is responsible for persistantly saving state, a mechanism
If the kernel is responsible for persistently saving state, a mechanism
called 'swsusp' (Swap Suspend) is used to write memory contents to
free swap space. swsusp has some restrictive requirements, but should
work in most cases. Some, albeit outdated, documentation can be found

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@ -0,0 +1,60 @@
Using swap files with software suspend (swsusp)
(C) 2006 Rafael J. Wysocki <rjw@sisk.pl>
The Linux kernel handles swap files almost in the same way as it handles swap
partitions and there are only two differences between these two types of swap
areas:
(1) swap files need not be contiguous,
(2) the header of a swap file is not in the first block of the partition that
holds it. From the swsusp's point of view (1) is not a problem, because it is
already taken care of by the swap-handling code, but (2) has to be taken into
consideration.
In principle the location of a swap file's header may be determined with the
help of appropriate filesystem driver. Unfortunately, however, it requires the
filesystem holding the swap file to be mounted, and if this filesystem is
journaled, it cannot be mounted during resume from disk. For this reason to
identify a swap file swsusp uses the name of the partition that holds the file
and the offset from the beginning of the partition at which the swap file's
header is located. For convenience, this offset is expressed in <PAGE_SIZE>
units.
In order to use a swap file with swsusp, you need to:
1) Create the swap file and make it active, eg.
# dd if=/dev/zero of=<swap_file_path> bs=1024 count=<swap_file_size_in_k>
# mkswap <swap_file_path>
# swapon <swap_file_path>
2) Use an application that will bmap the swap file with the help of the
FIBMAP ioctl and determine the location of the file's swap header, as the
offset, in <PAGE_SIZE> units, from the beginning of the partition which
holds the swap file.
3) Add the following parameters to the kernel command line:
resume=<swap_file_partition> resume_offset=<swap_file_offset>
where <swap_file_partition> is the partition on which the swap file is located
and <swap_file_offset> is the offset of the swap header determined by the
application in 2) (of course, this step may be carried out automatically
by the same application that determies the swap file's header offset using the
FIBMAP ioctl)
OR
Use a userland suspend application that will set the partition and offset
with the help of the SNAPSHOT_SET_SWAP_AREA ioctl described in
Documentation/power/userland-swsusp.txt (this is the only method to suspend
to a swap file allowing the resume to be initiated from an initrd or initramfs
image).
Now, swsusp will use the swap file in the same way in which it would use a swap
partition. In particular, the swap file has to be active (ie. be present in
/proc/swaps) so that it can be used for suspending.
Note that if the swap file used for suspending is deleted and recreated,
the location of its header need not be the same as before. Thus every time
this happens the value of the "resume_offset=" kernel command line parameter
has to be updated.

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@ -153,7 +153,7 @@ add:
If the thread is needed for writing the image to storage, you should
instead set the PF_NOFREEZE process flag when creating the thread (and
be very carefull).
be very careful).
Q: What is the difference between "platform", "shutdown" and
@ -297,20 +297,12 @@ system is shut down or suspended. Additionally use the encrypted
suspend image to prevent sensitive data from being stolen after
resume.
Q: Why can't we suspend to a swap file?
Q: Can I suspend to a swap file?
A: Because accessing swap file needs the filesystem mounted, and
filesystem might do something wrong (like replaying the journal)
during mount.
There are few ways to get that fixed:
1) Probably could be solved by modifying every filesystem to support
some kind of "really read-only!" option. Patches welcome.
2) suspend2 gets around that by storing absolute positions in on-disk
image (and blocksize), with resume parameter pointing directly to
suspend header.
A: Generally, yes, you can. However, it requires you to use the "resume=" and
"resume_offset=" kernel command line parameters, so the resume from a swap file
cannot be initiated from an initrd or initramfs image. See
swsusp-and-swap-files.txt for details.
Q: Is there a maximum system RAM size that is supported by swsusp?

View File

@ -9,9 +9,8 @@ done it already.
Now, to use the userland interface for software suspend you need special
utilities that will read/write the system memory snapshot from/to the
kernel. Such utilities are available, for example, from
<http://www.sisk.pl/kernel/utilities/suspend>. You may want to have
a look at them if you are going to develop your own suspend/resume
utilities.
<http://suspend.sourceforge.net>. You may want to have a look at them if you
are going to develop your own suspend/resume utilities.
The interface consists of a character device providing the open(),
release(), read(), and write() operations as well as several ioctl()
@ -21,9 +20,9 @@ be read from /sys/class/misc/snapshot/dev.
The device can be open either for reading or for writing. If open for
reading, it is considered to be in the suspend mode. Otherwise it is
assumed to be in the resume mode. The device cannot be open for reading
and writing. It is also impossible to have the device open more than once
at a time.
assumed to be in the resume mode. The device cannot be open for simultaneous
reading and writing. It is also impossible to have the device open more than
once at a time.
The ioctl() commands recognized by the device are:
@ -69,9 +68,46 @@ SNAPSHOT_FREE_SWAP_PAGES - free all swap pages allocated with
SNAPSHOT_SET_SWAP_FILE - set the resume partition (the last ioctl() argument
should specify the device's major and minor numbers in the old
two-byte format, as returned by the stat() function in the .st_rdev
member of the stat structure); it is recommended to always use this
call, because the code to set the resume partition could be removed from
future kernels
member of the stat structure)
SNAPSHOT_SET_SWAP_AREA - set the resume partition and the offset (in <PAGE_SIZE>
units) from the beginning of the partition at which the swap header is
located (the last ioctl() argument should point to a struct
resume_swap_area, as defined in kernel/power/power.h, containing the
resume device specification, as for the SNAPSHOT_SET_SWAP_FILE ioctl(),
and the offset); for swap partitions the offset is always 0, but it is
different to zero for swap files (please see
Documentation/swsusp-and-swap-files.txt for details).
The SNAPSHOT_SET_SWAP_AREA ioctl() is considered as a replacement for
SNAPSHOT_SET_SWAP_FILE which is regarded as obsolete. It is
recommended to always use this call, because the code to set the resume
partition may be removed from future kernels
SNAPSHOT_S2RAM - suspend to RAM; using this call causes the kernel to
immediately enter the suspend-to-RAM state, so this call must always
be preceded by the SNAPSHOT_FREEZE call and it is also necessary
to use the SNAPSHOT_UNFREEZE call after the system wakes up. This call
is needed to implement the suspend-to-both mechanism in which the
suspend image is first created, as though the system had been suspended
to disk, and then the system is suspended to RAM (this makes it possible
to resume the system from RAM if there's enough battery power or restore
its state on the basis of the saved suspend image otherwise)
SNAPSHOT_PMOPS - enable the usage of the pmops->prepare, pmops->enter and
pmops->finish methods (the in-kernel swsusp knows these as the "platform
method") which are needed on many machines to (among others) speed up
the resume by letting the BIOS skip some steps or to let the system
recognise the correct state of the hardware after the resume (in
particular on many machines this ensures that unplugged AC
adapters get correctly detected and that kacpid does not run wild after
the resume). The last ioctl() argument can take one of the three
values, defined in kernel/power/power.h:
PMOPS_PREPARE - make the kernel carry out the
pm_ops->prepare(PM_SUSPEND_DISK) operation
PMOPS_ENTER - make the kernel power off the system by calling
pm_ops->enter(PM_SUSPEND_DISK)
PMOPS_FINISH - make the kernel carry out the
pm_ops->finish(PM_SUSPEND_DISK) operation
The device's read() operation can be used to transfer the snapshot image from
the kernel. It has the following limitations:
@ -91,10 +127,12 @@ unfreeze user space processes frozen by SNAPSHOT_UNFREEZE if they are
still frozen when the device is being closed).
Currently it is assumed that the userland utilities reading/writing the
snapshot image from/to the kernel will use a swap partition, called the resume
partition, as storage space. However, this is not really required, as they
can use, for example, a special (blank) suspend partition or a file on a partition
that is unmounted before SNAPSHOT_ATOMIC_SNAPSHOT and mounted afterwards.
snapshot image from/to the kernel will use a swap parition, called the resume
partition, or a swap file as storage space (if a swap file is used, the resume
partition is the partition that holds this file). However, this is not really
required, as they can use, for example, a special (blank) suspend partition or
a file on a partition that is unmounted before SNAPSHOT_ATOMIC_SNAPSHOT and
mounted afterwards.
These utilities SHOULD NOT make any assumptions regarding the ordering of
data within the snapshot image, except for the image header that MAY be

View File

@ -6,6 +6,8 @@
IBM Corp.
(c) 2005 Becky Bruce <becky.bruce at freescale.com>,
Freescale Semiconductor, FSL SOC and 32-bit additions
(c) 2006 MontaVista Software, Inc.
Flash chip node definition
May 18, 2005: Rev 0.1 - Initial draft, no chapter III yet.
@ -33,13 +35,13 @@
- Change version 16 format to always align
property data to 4 bytes. Since tokens are
already aligned, that means no specific
required alignement between property size
required alignment between property size
and property data. The old style variable
alignment would make it impossible to do
"simple" insertion of properties using
memove (thanks Milton for
noticing). Updated kernel patch as well
- Correct a few more alignement constraints
- Correct a few more alignment constraints
- Add a chapter about the device-tree
compiler and the textural representation of
the tree that can be "compiled" by dtc.
@ -854,7 +856,7 @@ address which can extend beyond that limit.
console device if any. Typically, if you have serial devices on
your board, you may want to put the full path to the one set as
the default console in the firmware here, for the kernel to pick
it up as it's own default console. If you look at the funciton
it up as its own default console. If you look at the function
set_preferred_console() in arch/ppc64/kernel/setup.c, you'll see
that the kernel tries to find out the default console and has
knowledge of various types like 8250 serial ports. You may want
@ -1124,7 +1126,7 @@ should have the following properties:
- interrupt-parent : contains the phandle of the interrupt
controller which handles interrupts for this device
- interrupts : a list of tuples representing the interrupt
number and the interrupt sense and level for each interupt
number and the interrupt sense and level for each interrupt
for this device.
This information is used by the kernel to build the interrupt table
@ -1693,6 +1695,43 @@ platforms are moved over to use the flattened-device-tree model.
};
};
g) Flash chip nodes
Flash chips (Memory Technology Devices) are often used for solid state
file systems on embedded devices.
Required properties:
- device_type : has to be "rom"
- compatible : Should specify what this ROM device is compatible with
(i.e. "onenand"). Currently, this is most likely to be "direct-mapped"
(which corresponds to the MTD physmap mapping driver).
- regs : Offset and length of the register set (or memory mapping) for
the device.
Recommended properties :
- bank-width : Width of the flash data bus in bytes. Required
for the NOR flashes (compatible == "direct-mapped" and others) ONLY.
- partitions : Several pairs of 32-bit values where the first value is
partition's offset from the start of the device and the second one is
partition size in bytes with LSB used to signify a read only
partititon (so, the parition size should always be an even number).
- partition-names : The list of concatenated zero terminated strings
representing the partition names.
Example:
flash@ff000000 {
device_type = "rom";
compatible = "direct-mapped";
regs = <ff000000 01000000>;
bank-width = <4>;
partitions = <00000000 00f80000
00f80000 00080001>;
partition-names = "fs\0firmware";
};
More devices will be defined as this spec matures.

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@ -0,0 +1,189 @@
MPC52xx Device Tree Bindings
----------------------------
(c) 2006 Secret Lab Technologies Ltd
Grant Likely <grant.likely at secretlab.ca>
I - Introduction
================
Boards supported by the arch/powerpc architecture require device tree be
passed by the boot loader to the kernel at boot time. The device tree
describes what devices are present on the board and how they are
connected. The device tree can either be passed as a binary blob (as
described in Documentation/powerpc/booting-without-of.txt), or passed
by Open Firmare (IEEE 1275) compatible firmware using an OF compatible
client interface API.
This document specifies the requirements on the device-tree for mpc52xx
based boards. These requirements are above and beyond the details
specified in either the OpenFirmware spec or booting-without-of.txt
All new mpc52xx-based boards are expected to match this document. In
cases where this document is not sufficient to support a new board port,
this document should be updated as part of adding the new board support.
II - Philosophy
===============
The core of this document is naming convention. The whole point of
defining this convention is to reduce or eliminate the number of
special cases required to support a 52xx board. If all 52xx boards
follow the same convention, then generic 52xx support code will work
rather than coding special cases for each new board.
This section tries to capture the thought process behind why the naming
convention is what it is.
1. Node names
-------------
There is strong convention/requirements already established for children
of the root node. 'cpus' describes the processor cores, 'memory'
describes memory, and 'chosen' provides boot configuration. Other nodes
are added to describe devices attached to the processor local bus.
Following convention already established with other system-on-chip
processors, MPC52xx boards must have an 'soc5200' node as a child of the
root node.
The soc5200 node holds child nodes for all on chip devices. Child nodes
are typically named after the configured function. ie. the FEC node is
named 'ethernet', and a PSC in uart mode is named 'serial'.
2. device_type property
-----------------------
similar to the node name convention above; the device_type reflects the
configured function of a device. ie. 'serial' for a uart and 'spi' for
an spi controller. However, while node names *should* reflect the
configured function, device_type *must* match the configured function
exactly.
3. compatible property
----------------------
Since device_type isn't enough to match devices to drivers, there also
needs to be a naming convention for the compatible property. Compatible
is an list of device descriptions sorted from specific to generic. For
the mpc52xx, the required format for each compatible value is
<chip>-<device>[-<mode>]. At the minimum, the list shall contain two
items; the first specifying the exact chip, and the second specifying
mpc52xx for the chip.
ie. ethernet on mpc5200b: compatible = "mpc5200b-ethernet\0mpc52xx-ethernet"
The idea here is that most drivers will match to the most generic field
in the compatible list (mpc52xx-*), but can also test the more specific
field for enabling bug fixes or extra features.
Modal devices, like PSCs, also append the configured function to the
end of the compatible field. ie. A PSC in i2s mode would specify
"mpc52xx-psc-i2s", not "mpc52xx-i2s". This convention is chosen to
avoid naming conflicts with non-psc devices providing the same
function. For example, "mpc52xx-spi" and "mpc52xx-psc-spi" describe
the mpc5200 simple spi device and a PSC spi mode respectively.
If the soc device is more generic and present on other SOCs, the
compatible property can specify the more generic device type also.
ie. mscan: compatible = "mpc5200-mscan\0mpc52xx-mscan\0fsl,mscan";
At the time of writing, exact chip may be either 'mpc5200' or
'mpc5200b'.
Device drivers should always try to match as generically as possible.
III - Structure
===============
The device tree for an mpc52xx board follows the structure defined in
booting-without-of.txt with the following additional notes:
0) the root node
----------------
Typical root description node; see booting-without-of
1) The cpus node
----------------
The cpus node follows the basic layout described in booting-without-of.
The bus-frequency property holds the XLB bus frequency
The clock-frequency property holds the core frequency
2) The memory node
------------------
Typical memory description node; see booting-without-of.
3) The soc5200 node
-------------------
This node describes the on chip SOC peripherals. Every mpc52xx based
board will have this node, and as such there is a common naming
convention for SOC devices.
Required properties:
name type description
---- ---- -----------
device_type string must be "soc"
ranges int should be <0 baseaddr baseaddr+10000>
reg int must be <baseaddr 10000>
Recommended properties:
name type description
---- ---- -----------
compatible string should be "<chip>-soc\0mpc52xx-soc"
ie. "mpc5200b-soc\0mpc52xx-soc"
#interrupt-cells int must be <3>. If it is not defined
here then it must be defined in every
soc device node.
bus-frequency int IPB bus frequency in HZ. Clock rate
used by most of the soc devices.
Defining it here avoids needing it
added to every device node.
4) soc5200 child nodes
----------------------
Any on chip SOC devices available to Linux must appear as soc5200 child nodes.
Note: in the tables below, '*' matches all <chip> values. ie.
*-pic would translate to "mpc5200-pic\0mpc52xx-pic"
Required soc5200 child nodes:
name device_type compatible Description
---- ----------- ---------- -----------
cdm@<addr> cdm *-cmd Clock Distribution
pic@<addr> interrupt-controller *-pic need an interrupt
controller to boot
bestcomm@<addr> dma-controller *-bestcomm 52xx pic also requires
the bestcomm device
Recommended soc5200 child nodes; populate as needed for your board
name device_type compatible Description
---- ----------- ---------- -----------
gpt@<addr> gpt *-gpt General purpose timers
rtc@<addr> rtc *-rtc Real time clock
mscan@<addr> mscan *-mscan CAN bus controller
pci@<addr> pci *-pci PCI bridge
serial@<addr> serial *-psc-uart PSC in serial mode
i2s@<addr> i2s *-psc-i2s PSC in i2s mode
ac97@<addr> ac97 *-psc-ac97 PSC in ac97 mode
spi@<addr> spi *-psc-spi PSC in spi mode
irda@<addr> irda *-psc-irda PSC in IrDA mode
spi@<addr> spi *-spi MPC52xx spi device
ethernet@<addr> network *-fec MPC52xx ethernet device
ata@<addr> ata *-ata IDE ATA interface
i2c@<addr> i2c *-i2c I2C controller
usb@<addr> usb-ohci-be *-ohci,ohci-be USB controller
xlb@<addr> xlb *-xlb XLB arbritrator
IV - Extra Notes
================
1. Interrupt mapping
--------------------
The mpc52xx pic driver splits hardware IRQ numbers into two levels. The
split reflects the layout of the PIC hardware itself, which groups
interrupts into one of three groups; CRIT, MAIN or PERP. Also, the
Bestcomm dma engine has it's own set of interrupt sources which are
cascaded off of peripheral interrupt 0, which the driver interprets as a
fourth group, SDMA.
The interrupts property for device nodes using the mpc52xx pic consists
of three cells; <L1 L2 level>
L1 := [CRIT=0, MAIN=1, PERP=2, SDMA=3]
L2 := interrupt number; directly mapped from the value in the
"ICTL PerStat, MainStat, CritStat Encoded Register"
level := [LEVEL_HIGH=0, EDGE_RISING=1, EDGE_FALLING=2, LEVEL_LOW=3]

View File

@ -170,7 +170,7 @@ any point:
1) the 'head' pointer or an subsequent linked list pointer
is not a valid address of a user space word
2) the calculated location of the 'lock word' (address plus
'offset') is not the valud address of a 32 bit user space
'offset') is not the valid address of a 32 bit user space
word
3) if the list contains more than 1 million (subject to
future kernel configuration changes) elements.

View File

@ -181,7 +181,7 @@ for new threads, without the need of another syscall.]
So there is virtually zero overhead for tasks not using robust futexes,
and even for robust futex users, there is only one extra syscall per
thread lifetime, and the cleanup operation, if it happens, is fast and
straightforward. The kernel doesnt have any internal distinction between
straightforward. The kernel doesn't have any internal distinction between
robust and normal futexes.
If a futex is found to be held at exit time, the kernel sets the

View File

@ -1,12 +1,49 @@
Real Time Clock Driver for Linux
================================
Real Time Clock (RTC) Drivers for Linux
=======================================
When Linux developers talk about a "Real Time Clock", they usually mean
something that tracks wall clock time and is battery backed so that it
works even with system power off. Such clocks will normally not track
the local time zone or daylight savings time -- unless they dual boot
with MS-Windows -- but will instead be set to Coordinated Universal Time
(UTC, formerly "Greenwich Mean Time").
The newest non-PC hardware tends to just count seconds, like the time(2)
system call reports, but RTCs also very commonly represent time using
the Gregorian calendar and 24 hour time, as reported by gmtime(3).
Linux has two largely-compatible userspace RTC API families you may
need to know about:
* /dev/rtc ... is the RTC provided by PC compatible systems,
so it's not very portable to non-x86 systems.
* /dev/rtc0, /dev/rtc1 ... are part of a framework that's
supported by a wide variety of RTC chips on all systems.
Programmers need to understand that the PC/AT functionality is not
always available, and some systems can do much more. That is, the
RTCs use the same API to make requests in both RTC frameworks (using
different filenames of course), but the hardware may not offer the
same functionality. For example, not every RTC is hooked up to an
IRQ, so they can't all issue alarms; and where standard PC RTCs can
only issue an alarm up to 24 hours in the future, other hardware may
be able to schedule one any time in the upcoming century.
Old PC/AT-Compatible driver: /dev/rtc
--------------------------------------
All PCs (even Alpha machines) have a Real Time Clock built into them.
Usually they are built into the chipset of the computer, but some may
actually have a Motorola MC146818 (or clone) on the board. This is the
clock that keeps the date and time while your computer is turned off.
ACPI has standardized that MC146818 functionality, and extended it in
a few ways (enabling longer alarm periods, and wake-from-hibernate).
That functionality is NOT exposed in the old driver.
However it can also be used to generate signals from a slow 2Hz to a
relatively fast 8192Hz, in increments of powers of two. These signals
are reported by interrupt number 8. (Oh! So *that* is what IRQ 8 is
@ -63,9 +100,73 @@ Rather than write 50 pages describing the ioctl() and so on, it is
perhaps more useful to include a small test program that demonstrates
how to use them, and demonstrates the features of the driver. This is
probably a lot more useful to people interested in writing applications
that will be using this driver.
that will be using this driver. See the code at the end of this document.
(The original /dev/rtc driver was written by Paul Gortmaker.)
New portable "RTC Class" drivers: /dev/rtcN
--------------------------------------------
Because Linux supports many non-ACPI and non-PC platforms, some of which
have more than one RTC style clock, it needed a more portable solution
than expecting a single battery-backed MC146818 clone on every system.
Accordingly, a new "RTC Class" framework has been defined. It offers
three different userspace interfaces:
* /dev/rtcN ... much the same as the older /dev/rtc interface
* /sys/class/rtc/rtcN ... sysfs attributes support readonly
access to some RTC attributes.
* /proc/driver/rtc ... the first RTC (rtc0) may expose itself
using a procfs interface. More information is (currently) shown
here than through sysfs.
The RTC Class framework supports a wide variety of RTCs, ranging from those
integrated into embeddable system-on-chip (SOC) processors to discrete chips
using I2C, SPI, or some other bus to communicate with the host CPU. There's
even support for PC-style RTCs ... including the features exposed on newer PCs
through ACPI.
The new framework also removes the "one RTC per system" restriction. For
example, maybe the low-power battery-backed RTC is a discrete I2C chip, but
a high functionality RTC is integrated into the SOC. That system might read
the system clock from the discrete RTC, but use the integrated one for all
other tasks, because of its greater functionality.
The ioctl() calls supported by /dev/rtc are also supported by the RTC class
framework. However, because the chips and systems are not standardized,
some PC/AT functionality might not be provided. And in the same way, some
newer features -- including those enabled by ACPI -- are exposed by the
RTC class framework, but can't be supported by the older driver.
* RTC_RD_TIME, RTC_SET_TIME ... every RTC supports at least reading
time, returning the result as a Gregorian calendar date and 24 hour
wall clock time. To be most useful, this time may also be updated.
* RTC_AIE_ON, RTC_AIE_OFF, RTC_ALM_SET, RTC_ALM_READ ... when the RTC
is connected to an IRQ line, it can often issue an alarm IRQ up to
24 hours in the future.
* RTC_WKALM_SET, RTC_WKALM_READ ... RTCs that can issue alarms beyond
the next 24 hours use a slightly more powerful API, which supports
setting the longer alarm time and enabling its IRQ using a single
request (using the same model as EFI firmware).
* RTC_UIE_ON, RTC_UIE_OFF ... if the RTC offers IRQs, it probably
also offers update IRQs whenever the "seconds" counter changes.
If needed, the RTC framework can emulate this mechanism.
* RTC_PIE_ON, RTC_PIE_OFF, RTC_IRQP_SET, RTC_IRQP_READ ... another
feature often accessible with an IRQ line is a periodic IRQ, issued
at settable frequencies (usually 2^N Hz).
In many cases, the RTC alarm can be a system wake event, used to force
Linux out of a low power sleep state (or hibernation) back to a fully
operational state. For example, a system could enter a deep power saving
state until it's time to execute some scheduled tasks.
Paul Gortmaker
-------------------- 8< ---------------- 8< -----------------------------
@ -83,25 +184,46 @@ that will be using this driver.
*/
#include <stdio.h>
#include <stdlib.h>
#include <linux/rtc.h>
#include <sys/ioctl.h>
#include <sys/time.h>
#include <sys/types.h>
#include <fcntl.h>
#include <unistd.h>
#include <stdlib.h>
#include <errno.h>
int main(void) {
/*
* This expects the new RTC class driver framework, working with
* clocks that will often not be clones of what the PC-AT had.
* Use the command line to specify another RTC if you need one.
*/
static const char default_rtc[] = "/dev/rtc0";
int main(int argc, char **argv)
{
int i, fd, retval, irqcount = 0;
unsigned long tmp, data;
struct rtc_time rtc_tm;
const char *rtc = default_rtc;
fd = open ("/dev/rtc", O_RDONLY);
switch (argc) {
case 2:
rtc = argv[1];
/* FALLTHROUGH */
case 1:
break;
default:
fprintf(stderr, "usage: rtctest [rtcdev]\n");
return 1;
}
fd = open(rtc, O_RDONLY);
if (fd == -1) {
perror("/dev/rtc");
perror(rtc);
exit(errno);
}
@ -110,11 +232,17 @@ fprintf(stderr, "\n\t\t\tRTC Driver Test Example.\n\n");
/* Turn on update interrupts (one per second) */
retval = ioctl(fd, RTC_UIE_ON, 0);
if (retval == -1) {
if (errno == ENOTTY) {
fprintf(stderr,
"\n...Update IRQs not supported.\n");
goto test_READ;
}
perror("ioctl");
exit(errno);
}
fprintf(stderr, "Counting 5 update (1/sec) interrupts from reading /dev/rtc:");
fprintf(stderr, "Counting 5 update (1/sec) interrupts from reading %s:",
rtc);
fflush(stderr);
for (i=1; i<6; i++) {
/* This read will block */
@ -160,6 +288,7 @@ if (retval == -1) {
exit(errno);
}
test_READ:
/* Read the RTC time/date */
retval = ioctl(fd, RTC_RD_TIME, &rtc_tm);
if (retval == -1) {
@ -186,6 +315,11 @@ if (rtc_tm.tm_hour == 24)
retval = ioctl(fd, RTC_ALM_SET, &rtc_tm);
if (retval == -1) {
if (errno == ENOTTY) {
fprintf(stderr,
"\n...Alarm IRQs not supported.\n");
goto test_PIE;
}
perror("ioctl");
exit(errno);
}
@ -225,13 +359,19 @@ if (retval == -1) {
exit(errno);
}
test_PIE:
/* Read periodic IRQ rate */
retval = ioctl(fd, RTC_IRQP_READ, &tmp);
if (retval == -1) {
/* not all RTCs support periodic IRQs */
if (errno == ENOTTY) {
fprintf(stderr, "\nNo periodic IRQ support\n");
return 0;
}
perror("ioctl");
exit(errno);
}
fprintf(stderr, "\nPeriodic IRQ rate was %ldHz.\n", tmp);
fprintf(stderr, "\nPeriodic IRQ rate is %ldHz.\n", tmp);
fprintf(stderr, "Counting 20 interrupts at:");
fflush(stderr);
@ -241,6 +381,12 @@ for (tmp=2; tmp<=64; tmp*=2) {
retval = ioctl(fd, RTC_IRQP_SET, tmp);
if (retval == -1) {
/* not all RTCs can change their periodic IRQ rate */
if (errno == ENOTTY) {
fprintf(stderr,
"\n...Periodic IRQ rate is fixed\n");
goto done;
}
perror("ioctl");
exit(errno);
}
@ -275,11 +421,10 @@ for (tmp=2; tmp<=64; tmp*=2) {
}
}
done:
fprintf(stderr, "\n\n\t\t\t *** Test complete ***\n");
fprintf(stderr, "\nTyping \"cat /proc/interrupts\" will show %d more events on IRQ 8.\n\n",
irqcount);
close(fd);
return 0;
} /* end main */
return 0;
}

View File

@ -74,7 +74,7 @@ Command line parameters
Note: While already known devices can be added to the list of devices to be
ignored, there will be no effect on then. However, if such a device
disappears and then reappeares, it will then be ignored.
disappears and then reappears, it will then be ignored.
For example,
"echo add 0.0.a000-0.0.accc, 0.0.af00-0.0.afff > /proc/cio_ignore"
@ -82,7 +82,7 @@ Command line parameters
devices.
The devices can be specified either by bus id (0.0.abcd) or, for 2.4 backward
compatibilty, by the device number in hexadecimal (0xabcd or abcd).
compatibility, by the device number in hexadecimal (0xabcd or abcd).
* /proc/s390dbf/cio_*/ (S/390 debug feature)

View File

@ -7,7 +7,7 @@
Overview of Document:
=====================
This document is intended to give an good overview of how to debug
This document is intended to give a good overview of how to debug
Linux for s/390 & z/Architecture. It isn't intended as a complete reference & not a
tutorial on the fundamentals of C & assembly. It doesn't go into
390 IO in any detail. It is intended to complement the documents in the
@ -502,7 +502,7 @@ Notes:
------
1) The only requirement is that registers which are used
by the callee are saved, e.g. the compiler is perfectly
capible of using r11 for purposes other than a frame a
capable of using r11 for purposes other than a frame a
frame pointer if a frame pointer is not needed.
2) In functions with variable arguments e.g. printf the calling procedure
is identical to one without variable arguments & the same number of
@ -846,7 +846,7 @@ of time searching for debugging info. The following self explanatory line should
instead if the code isn't compiled -g, as it is much faster:
objdump --disassemble-all --syms vmlinux > vmlinux.lst
As hard drive space is valuble most of us use the following approach.
As hard drive space is valuable most of us use the following approach.
1) Look at the emitted psw on the console to find the crash address in the kernel.
2) Look at the file System.map ( in the linux directory ) produced when building
the kernel to find the closest address less than the current PSW to find the
@ -902,7 +902,7 @@ A. It is a tool for intercepting calls to the kernel & logging them
to a file & on the screen.
Q. What use is it ?
A. You can used it to find out what files a particular program opens.
A. You can use it to find out what files a particular program opens.
@ -911,7 +911,7 @@ Example 1
If you wanted to know does ping work but didn't have the source
strace ping -c 1 127.0.0.1
& then look at the man pages for each of the syscalls below,
( In fact this is sometimes easier than looking at some spagetti
( In fact this is sometimes easier than looking at some spaghetti
source which conditionally compiles for several architectures ).
Not everything that it throws out needs to make sense immediately.
@ -1037,7 +1037,7 @@ e.g. man strace, man alarm, man socket.
Performance Debugging
=====================
gcc is capible of compiling in profiling code just add the -p option
gcc is capable of compiling in profiling code just add the -p option
to the CFLAGS, this obviously affects program size & performance.
This can be used by the gprof gnu profiling tool or the
gcov the gnu code coverage tool ( code coverage is a means of testing
@ -1419,7 +1419,7 @@ On a SMP guest issue a command to all CPUs try prefixing the command with cpu al
To issue a command to a particular cpu try cpu <cpu number> e.g.
CPU 01 TR I R 2000.3000
If you are running on a guest with several cpus & you have a IO related problem
& cannot follow the flow of code but you know it isnt smp related.
& cannot follow the flow of code but you know it isn't smp related.
from the bash prompt issue
shutdown -h now or halt.
do a Q CPUS to find out how many cpus you have
@ -1602,7 +1602,7 @@ V000FFFD0 00010400 80010802 8001085A 000FFFA0
our 3rd return address is 8001085A
as the 04B52002 looks suspiciously like rubbish it is fair to assume that the kernel entry routines
for the sake of optimisation dont set up a backchain.
for the sake of optimisation don't set up a backchain.
now look at System.map to see if the addresses make any sense.
@ -1651,7 +1651,7 @@ HALT SUBCHANNEL,MODIFY SUBCHANNEL,RESUME SUBCHANNEL,START SUBCHANNEL,STORE SUBCH
TEST SUBCHANNEL ) we use this as the ID of the device we wish to talk to, the most
important of these instructions are START SUBCHANNEL ( to start IO ), TEST SUBCHANNEL ( to check
whether the IO completed successfully ), & HALT SUBCHANNEL ( to kill IO ), a subchannel
can have up to 8 channel paths to a device this offers redunancy if one is not available.
can have up to 8 channel paths to a device this offers redundancy if one is not available.
Device Number:
@ -1659,7 +1659,7 @@ This number remains static & Is closely tied to the hardware, there are 65536 of
also they are made up of a CHPID ( Channel Path ID, the most significant 8 bits )
& another lsb 8 bits. These remain static even if more devices are inserted or removed
from the hardware, there is a 1 to 1 mapping between Subchannels & Device Numbers provided
devices arent inserted or removed.
devices aren't inserted or removed.
Channel Control Words:
CCWS are linked lists of instructions initially pointed to by an operation request block (ORB),
@ -1674,7 +1674,7 @@ concurrently, you check how the IO went on by issuing a TEST SUBCHANNEL at each
from which you receive an Interruption response block (IRB). If you get channel & device end
status in the IRB without channel checks etc. your IO probably went okay. If you didn't you
probably need a doctor to examine the IRB & extended status word etc.
If an error occurs, more sophistocated control units have a facitity known as
If an error occurs, more sophisticated control units have a facility known as
concurrent sense this means that if an error occurs Extended sense information will
be presented in the Extended status word in the IRB if not you have to issue a
subsequent SENSE CCW command after the test subchannel.
@ -2050,7 +2050,7 @@ list test.c:1,10
directory:
Adds directories to be searched for source if gdb cannot find the source.
(note it is a bit sensititive about slashes)
(note it is a bit sensitive about slashes)
e.g. To add the root of the filesystem to the searchpath do
directory //
@ -2152,7 +2152,7 @@ program as if it just crashed on your system, it is usually called core & create
current working directory.
This is very useful in that a customer can mail a core dump to a technical support department
& the technical support department can reconstruct what happened.
Provided the have an identical copy of this program with debugging symbols compiled in &
Provided they have an identical copy of this program with debugging symbols compiled in &
the source base of this build is available.
In short it is far more useful than something like a crash log could ever hope to be.

View File

@ -98,7 +98,7 @@ The following chapters describe the I/O related interface routines the
Linux/390 common device support (CDS) provides to allow for device specific
driver implementations on the IBM ESA/390 hardware platform. Those interfaces
intend to provide the functionality required by every device driver
implementaion to allow to drive a specific hardware device on the ESA/390
implementation to allow to drive a specific hardware device on the ESA/390
platform. Some of the interface routines are specific to Linux/390 and some
of them can be found on other Linux platforms implementations too.
Miscellaneous function prototypes, data declarations, and macro definitions
@ -114,7 +114,7 @@ the ESA/390 architecture has implemented a so called channel subsystem, that
provides a unified view of the devices physically attached to the systems.
Though the ESA/390 hardware platform knows about a huge variety of different
peripheral attachments like disk devices (aka. DASDs), tapes, communication
controllers, etc. they can all by accessed by a well defined access method and
controllers, etc. they can all be accessed by a well defined access method and
they are presenting I/O completion a unified way : I/O interruptions. Every
single device is uniquely identified to the system by a so called subchannel,
where the ESA/390 architecture allows for 64k devices be attached.
@ -338,7 +338,7 @@ DOIO_REPORT_ALL - report all interrupt conditions
The ccw_device_start() function returns :
0 - successful completion or request successfully initiated
-EBUSY - The device is currently processing a previous I/O request, or ther is
-EBUSY - The device is currently processing a previous I/O request, or there is
a status pending at the device.
-ENODEV - cdev is invalid, the device is not operational or the ccw_device is
not online.
@ -361,7 +361,7 @@ first:
-EIO: the common I/O layer terminated the request due to an error state
If the concurrent sense flag in the extended status word in the irb is set, the
field irb->scsw.count describes the numer of device specific sense bytes
field irb->scsw.count describes the number of device specific sense bytes
available in the extended control word irb->scsw.ecw[0]. No device sensing by
the device driver itself is required.
@ -410,7 +410,7 @@ ccw_device_start() must be called disabled and with the ccw device lock held.
The device driver is allowed to issue the next ccw_device_start() call from
within its interrupt handler already. It is not required to schedule a
bottom-half, unless an non deterministically long running error recovery procedure
bottom-half, unless a non deterministically long running error recovery procedure
or similar needs to be scheduled. During I/O processing the Linux/390 generic
I/O device driver support has already obtained the IRQ lock, i.e. the handler
must not try to obtain it again when calling ccw_device_start() or we end in a
@ -431,7 +431,7 @@ information prior to device-end the device driver urgently relies on. In this
case all I/O interruptions are presented to the device driver until final
status is recognized.
If a device is able to recover from asynchronosly presented I/O errors, it can
If a device is able to recover from asynchronously presented I/O errors, it can
perform overlapping I/O using the DOIO_EARLY_NOTIFICATION flag. While some
devices always report channel-end and device-end together, with a single
interrupt, others present primary status (channel-end) when the channel is

View File

@ -17,8 +17,8 @@ arch/s390/crypto directory.
2. Probing for availability of MSA
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
It should be possible to use Kernels with the z990 crypto implementations both
on machines with MSA available an on those without MSA (pre z990 or z990
without MSA). Therefore a simple probing mechanisms has been implemented:
on machines with MSA available and on those without MSA (pre z990 or z990
without MSA). Therefore a simple probing mechanism has been implemented:
In the init function of each crypto module the availability of MSA and of the
respective crypto algorithm in particular will be tested. If the algorithm is
available the module will load and register its algorithm with the crypto API.
@ -26,7 +26,7 @@ available the module will load and register its algorithm with the crypto API.
If the respective crypto algorithm is not available, the init function will
return -ENOSYS. In that case a fallback to the standard software implementation
of the crypto algorithm must be taken ( -> the standard crypto modules are
also build when compiling the kernel).
also built when compiling the kernel).
3. Ensuring z990 crypto module preference
@ -75,8 +75,8 @@ name of the respective module is given in square brackets.
- SHA1 Digest Algorithm [sha1 -> sha1_z990]
- DES Encrypt/Decrypt Algorithm (64bit key) [des -> des_z990]
- Tripple DES Encrypt/Decrypt Algorithm (128bit key) [des3_ede128 -> des_z990]
- Tripple DES Encrypt/Decrypt Algorithm (192bit key) [des3_ede -> des_z990]
- Triple DES Encrypt/Decrypt Algorithm (128bit key) [des3_ede128 -> des_z990]
- Triple DES Encrypt/Decrypt Algorithm (192bit key) [des3_ede -> des_z990]
In order to load, for example, the sha1_z990 module when the sha1 algorithm is
requested (see 3.2.) add 'alias sha1 sha1_z990' to /etc/modprobe.conf.

View File

@ -36,7 +36,7 @@ switches to the next debug area. This is done in order to be sure
that the records which describe the origin of the exception are not
overwritten when a wrap around for the current area occurs.
The debug areas itselve are also ordered in form of a ring buffer.
The debug areas themselves are also ordered in form of a ring buffer.
When an exception is thrown in the last debug area, the following debug
entries are then written again in the very first area.
@ -55,7 +55,7 @@ The debug logs can be inspected in a live system through entries in
the debugfs-filesystem. Under the toplevel directory "s390dbf" there is
a directory for each registered component, which is named like the
corresponding component. The debugfs normally should be mounted to
/sys/kernel/debug therefore the debug feature can be accessed unter
/sys/kernel/debug therefore the debug feature can be accessed under
/sys/kernel/debug/s390dbf.
The content of the directories are files which represent different views
@ -87,11 +87,11 @@ There are currently 2 possible triggers, which stop the debug feature
globally. The first possibility is to use the "debug_active" sysctl. If
set to 1 the debug feature is running. If "debug_active" is set to 0 the
debug feature is turned off.
The second trigger which stops the debug feature is an kernel oops.
The second trigger which stops the debug feature is a kernel oops.
That prevents the debug feature from overwriting debug information that
happened before the oops. After an oops you can reactivate the debug feature
by piping 1 to /proc/sys/s390dbf/debug_active. Nevertheless, its not
suggested to use an oopsed kernel in an production environment.
suggested to use an oopsed kernel in a production environment.
If you want to disallow the deactivation of the debug feature, you can use
the "debug_stoppable" sysctl. If you set "debug_stoppable" to 0 the debug
feature cannot be stopped. If the debug feature is already stopped, it

View File

@ -127,7 +127,7 @@ The following information is available in this file:
- Correct a reference to free'ed memory during controller
shutdown.
- Reset the bus on an SE->LVD change. This is required
to reset our transcievers.
to reset our transceivers.
1.3.5 (March 24th, 2003)
- Fix a few register window mode bugs.
@ -169,7 +169,7 @@ The following information is available in this file:
1.3.0 (January 21st, 2003)
- Full regression testing for all U320 products completed.
- Added abort and target/lun reset error recovery handler and
interrupt coalessing.
interrupt coalescing.
1.2.0 (November 14th, 2002)
- Added support for Domain Validation

View File

@ -256,7 +256,7 @@ linux-1.1.x and fairly stable since linux-1.2.x, and are also in FreeBSD
En/Disable High Byte LVD Termination
The upper 2 bits that deal with LVD termination only apply to Ultra2
controllers. Futhermore, due to the current Ultra2 controller
controllers. Furthermore, due to the current Ultra2 controller
designs, these bits are tied together such that setting either bit
enables both low and high byte LVD termination. It is not possible
to only set high or low byte LVD termination in this manner. This is
@ -436,7 +436,7 @@ linux-1.1.x and fairly stable since linux-1.2.x, and are also in FreeBSD
the commas to periods, insmod won't interpret this as more than one
string and write junk into our binary image. I consider it a bug in
the insmod program that even if you wrap your string in quotes (quotes
that pass the shell mind you and that insmod sees) it still treates
that pass the shell mind you and that insmod sees) it still treats
a comma inside of those quotes as starting a new variable, resulting
in memory scribbles if you don't switch the commas to periods.

View File

@ -461,7 +461,7 @@
This needs the RD-Bit to be disabled on IM_OTHER_SCSI_CMD_CMD which
allows data to be written from the system to the device. It is a
necessary step to be allowed to set blocksize of SCSI-tape-drives and
the tape-speed, whithout confusing the SCSI-Subsystem.
the tape-speed, without confusing the SCSI-Subsystem.
2) The recognition of a tape is included in the check_devices routine.
This is done by checking for TYPE_TAPE, that is already defined in
the kernel-scsi-environment. The markup of a tape is done in the
@ -710,8 +710,8 @@
of troubles with some controllers and after I wanted to apply some
extensions, it jumped out in the same situation, on my w/cache, as like
on D. Weinehalls' Model 56, having integrated SCSI. This gave me the
descissive hint to move the code-part out and declare it global. Now,
it seems to work by far much better an more stable. Let us see, what
decisive hint to move the code-part out and declare it global. Now
it seems to work far better and more stable. Let us see what
the world thinks of it...
3) By the way, only Sony DAT-drives seem to show density code 0x13. A
test with a HP drive gave right results, so the problem is vendor-
@ -822,10 +822,10 @@
A long period of collecting bugreports from all corners of the world
now lead to the following corrections to the code:
1) SCSI-2 F/W support crashed with a COMMAND ERROR. The reason for this
was, that it is possible to disbale Fast-SCSI for the external bus.
The feature-control command, where this crash appeared regularly tried
was that it is possible to disable Fast-SCSI for the external bus.
The feature-control command, where this crash appeared regularly, tried
to set the maximum speed of 10MHz synchronous transfer speed and that
reports a COMMAND ERROR, if external bus Fast-SCSI is disabled. Now,
reports a COMMAND ERROR if external bus Fast-SCSI is disabled. Now,
the feature-command probes down from maximum speed until the adapter
stops to complain, which is at the same time the maximum possible
speed selected in the reference program. So, F/W external can run at
@ -920,7 +920,7 @@
completed in such a way, that they are now completely conform to the
demands in the technical description of IBM. Main candidates were the
DEVICE_INQUIRY, REQUEST_SENSE and DEVICE_CAPACITY commands. They must
be tranferred by bypassing the internal command buffer of the adapter
be transferred by bypassing the internal command buffer of the adapter
or else the response can be a random result. GET_POS_INFO would be more
safe in usage, if one could use the SUPRESS_EXCEPTION_SHORT, but this
is not allowed by the technical references of IBM. (Sorry, folks, the

View File

@ -24,7 +24,7 @@ UPDATE NEWS: version 1.32 - 28 Mar 98
UPDATE NEWS: version 1.31 - 6 Jul 97
Fixed a bug that caused incorrect SCSI status bytes to be
returned from commands sent to LUN's greater than 0. This
returned from commands sent to LUNs greater than 0. This
means that CDROM changers work now! Fixed a bug in the
handling of command-line arguments when loaded as a module.
Also put all the header data in in2000.h where it belongs.

View File

@ -393,7 +393,7 @@ struct sas_task {
task_proto -- _one_ of enum sas_proto
scatter -- pointer to scatter gather list array
num_scatter -- number of elements in scatter
total_xfer_len -- total number of bytes expected to be transfered
total_xfer_len -- total number of bytes expected to be transferred
data_dir -- PCI_DMA_...
task_done -- callback when the task has finished execution
};

View File

@ -115,7 +115,7 @@ SCSI standard documentations are available at SYMBIOS ftp server:
ftp://ftp.symbios.com/
Usefull SCSI tools written by Eric Youngdale are available at tsx-11:
Useful SCSI tools written by Eric Youngdale are available at tsx-11:
ftp://tsx-11.mit.edu/pub/linux/ALPHA/scsi/scsiinfo-X.Y.tar.gz
ftp://tsx-11.mit.edu/pub/linux/ALPHA/scsi/scsidev-X.Y.tar.gz

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@ -88,7 +88,7 @@ If the module finds the changer, it prints some messages about the
device [ try "dmesg" if you don't see anything ] and should show up in
/proc/devices. If not.... some changers use ID ? / LUN 0 for the
device and ID ? / LUN 1 for the robot mechanism. But Linux does *not*
look for LUN's other than 0 as default, becauce there are to many
look for LUNs other than 0 as default, because there are too many
broken devices. So you can try:
1) echo "scsi add-single-device 0 0 ID 1" > /proc/scsi/scsi
@ -107,7 +107,7 @@ because the kernel will translate the error codes into human-readable
strings then.
You can display these messages with the dmesg command (or check the
logfiles). If you email me some question becauce of a problem with the
logfiles). If you email me some question because of a problem with the
driver, please include these messages.

View File

@ -75,7 +75,7 @@ with the command.
- otherwise
scsi_eh_scmd_add(scmd, 0) is invoked for the command. See
[1-3] for details of this funciton.
[1-3] for details of this function.
[1-2-2] Completing a scmd w/ timeout

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@ -375,7 +375,6 @@ Summary:
scsi_add_device - creates new scsi device (lu) instance
scsi_add_host - perform sysfs registration and set up transport class
scsi_adjust_queue_depth - change the queue depth on a SCSI device
scsi_assign_lock - replace default host_lock with given lock
scsi_bios_ptable - return copy of block device's partition table
scsi_block_requests - prevent further commands being queued to given host
scsi_deactivate_tcq - turn off tag command queueing
@ -488,20 +487,6 @@ void scsi_adjust_queue_depth(struct scsi_device * sdev, int tagged,
int tags)
/**
* scsi_assign_lock - replace default host_lock with given lock
* @shost: a pointer to a scsi host instance
* @lock: pointer to lock to replace host_lock for this host
*
* Returns nothing
*
* Might block: no
*
* Defined in: include/scsi/scsi_host.h .
**/
void scsi_assign_lock(struct Scsi_Host *shost, spinlock_t *lock)
/**
* scsi_bios_ptable - return copy of block device's partition table
* @dev: pointer to block device
@ -1366,17 +1351,11 @@ Locks
Each struct Scsi_Host instance has a spin_lock called struct
Scsi_Host::default_lock which is initialized in scsi_host_alloc() [found in
hosts.c]. Within the same function the struct Scsi_Host::host_lock pointer
is initialized to point at default_lock with the scsi_assign_lock() function.
Thereafter lock and unlock operations performed by the mid level use the
struct Scsi_Host::host_lock pointer.
is initialized to point at default_lock. Thereafter lock and unlock
operations performed by the mid level use the struct Scsi_Host::host_lock
pointer. Previously drivers could override the host_lock pointer but
this is not allowed anymore.
LLDs can override the use of struct Scsi_Host::default_lock by
using scsi_assign_lock(). The earliest opportunity to do this would
be in the detect() function after it has invoked scsi_register(). It
could be replaced by a coarser grain lock (e.g. per driver) or a
lock of equal granularity (i.e. per host). Using finer grain locks
(e.g. per SCSI device) may be possible by juggling locks in
queuecommand().
Autosense
=========

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@ -261,7 +261,7 @@ pairs are separated with a comma (no spaces allowed). A colon can be
used instead of the equal mark. The definition is prepended by the
string st=. Here is an example:
st=buffer_kbs:64,write_threhold_kbs:60
st=buffer_kbs:64,write_threshold_kbs:60
The following syntax used by the old kernel versions is also supported:

View File

@ -609,7 +609,7 @@ appropriate mailing lists or news-groups. Send me a copy in order to
be sure I will receive it. Obviously, a bug in the driver code is
possible.
My cyrrent email address: Gerard Roudier <groudier@free.fr>
My current email address: Gerard Roudier <groudier@free.fr>
Allowing disconnections is important if you use several devices on
your SCSI bus but often causes problems with buggy devices.

View File

@ -942,13 +942,13 @@ replicas continue to be exactly same.
->mnt_slave
->mnt_master
->mnt_share links togather all the mount to/from which this vfsmount
->mnt_share links together all the mount to/from which this vfsmount
send/receives propagation events.
->mnt_slave_list links all the mounts to which this vfsmount propagates
to.
->mnt_slave links togather all the slaves that its master vfsmount
->mnt_slave links together all the slaves that its master vfsmount
propagates to.
->mnt_master points to the master vfsmount from which this vfsmount

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@ -753,7 +753,7 @@ Prior to version 0.9.0rc4 options had a 'snd_' prefix. This was removed.
position_fix - Fix DMA pointer (0 = auto, 1 = none, 2 = POSBUF, 3 = FIFO size)
single_cmd - Use single immediate commands to communicate with
codecs (for debugging only)
disable_msi - Disable Message Signaled Interrupt (MSI)
enable_msi - Enable Message Signaled Interrupt (MSI) (default = off)
This module supports one card and autoprobe.
@ -955,7 +955,7 @@ Prior to version 0.9.0rc4 options had a 'snd_' prefix. This was removed.
dmx6fire, dsp24, dsp24_value, dsp24_71, ez8,
phase88, mediastation
omni - Omni I/O support for MidiMan M-Audio Delta44/66
cs8427_timeout - reset timeout for the CS8427 chip (S/PDIF transciever)
cs8427_timeout - reset timeout for the CS8427 chip (S/PDIF transceiver)
in msec resolution, default value is 500 (0.5 sec)
This module supports multiple cards and autoprobe. Note: The consumer part

View File

@ -6,7 +6,7 @@ This is based on SB-Live-mixer.txt.
The EMU10K2 chips have a DSP part which can be programmed to support
various ways of sample processing, which is described here.
(This acticle does not deal with the overall functionality of the
(This article does not deal with the overall functionality of the
EMU10K2 chips. See the manuals section for further details.)
The ALSA driver programs this portion of chip by default code

View File

@ -5,7 +5,7 @@
The EMU10K1 chips have a DSP part which can be programmed to support
various ways of sample processing, which is described here.
(This acticle does not deal with the overall functionality of the
(This article does not deal with the overall functionality of the
EMU10K1 chips. See the manuals section for further details.)
The ALSA driver programs this portion of chip by default code

View File

@ -62,9 +62,6 @@ consider the following facts about the Linux kernel:
- different structures can contain different fields
- Some functions may not be implemented at all, (i.e. some locks
compile away to nothing for non-SMP builds.)
- Parameter passing of variables from function to function can be
done in different ways (the CONFIG_REGPARM option controls
this.)
- Memory within the kernel can be aligned in different ways,
depending on the build options.
- Linux runs on a wide range of different processor architectures.

View File

@ -50,7 +50,7 @@ Review cycle:
Contact the kernel security team for more details on this procedure.
Review committe:
Review committee:
- This is made up of a number of kernel developers who have volunteered for
this task, and a few that haven't.

View File

@ -146,7 +146,7 @@ or otherwise protected/tainted binaries. The modes are
readable by root only. This allows the end user to remove
such a dump but not access it directly. For security reasons
core dumps in this mode will not overwrite one another or
other files. This mode is appropriate when adminstrators are
other files. This mode is appropriate when administrators are
attempting to debug problems in a normal environment.
==============================================================

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@ -27,6 +27,7 @@ show up in /proc/sys/kernel:
- hotplug
- java-appletviewer [ binfmt_java, obsolete ]
- java-interpreter [ binfmt_java, obsolete ]
- kstack_depth_to_print [ X86 only ]
- l2cr [ PPC only ]
- modprobe ==> Documentation/kmod.txt
- msgmax
@ -170,6 +171,13 @@ This flag controls the L2 cache of G3 processor boards. If
==============================================================
kstack_depth_to_print: (X86 only)
Controls the number of words to print when dumping the raw
kernel stack.
==============================================================
osrelease, ostype & version:
# cat osrelease

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