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KVM/arm fixes for 5.3 

- A bunch of switch/case fall-through annotation, fixing one actual bug
 - Fix PMU reset bug
 - Add missing exception class debug strings
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Merge tag 'kvmarm-fixes-for-5.3' of git://git.kernel.org/pub/scm/linux/kernel/git/kvmarm/kvmarm into HEAD

KVM/arm fixes for 5.3

- A bunch of switch/case fall-through annotation, fixing one actual bug
- Fix PMU reset bug
- Add missing exception class debug strings
alistair/sunxi64-5.4-dsi
Paolo Bonzini 2019-08-09 16:53:39 +02:00
parent c096397c78 cdb2d3ee04
commit 0e1c438c44
5794 changed files with 623707 additions and 111796 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

1
.gitignore vendored
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@ -30,6 +30,7 @@
*.lz4
*.lzma
*.lzo
*.mod
*.mod.c
*.o
*.o.*

3
CREDITS
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@ -1770,7 +1770,6 @@ S: USA
N: Dave Jones
E: davej@codemonkey.org.uk
W: http://www.codemonkey.org.uk
D: Assorted VIA x86 support.
D: 2.5 AGPGART overhaul.
D: CPUFREQ maintenance.
@ -3120,7 +3119,7 @@ S: France
N: Rik van Riel
E: riel@redhat.com
W: http://www.surriel.com/
D: Linux-MM site, Documentation/sysctl/*, swap/mm readaround
D: Linux-MM site, Documentation/admin-guide/sysctl/*, swap/mm readaround
D: kswapd fixes, random kernel hacker, rmap VM,
D: nl.linux.org administrator, minor scheduler additions
S: Red Hat Boston

2
Documentation/ABI/obsolete/sysfs-gpio
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@ -11,7 +11,7 @@ Description:
Kernel code may export it for complete or partial access.
GPIOs are identified as they are inside the kernel, using integers in
the range 0..INT_MAX. See Documentation/gpio for more information.
the range 0..INT_MAX. See Documentation/admin-guide/gpio for more information.
/sys/class/gpio
/export ... asks the kernel to export a GPIO to userspace

2
Documentation/ABI/removed/sysfs-class-rfkill
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@ -1,6 +1,6 @@
rfkill - radio frequency (RF) connector kill switch support
For details to this subsystem look at Documentation/rfkill.txt.
For details to this subsystem look at Documentation/driver-api/rfkill.rst.
What: /sys/class/rfkill/rfkill[0-9]+/claim
Date: 09-Jul-2007

17
Documentation/ABI/stable/sysfs-class-infiniband
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@ -423,23 +423,6 @@ Description:
(e.g. driver restart on the VM which owns the VF).
sysfs interface for NetEffect RNIC Low-Level iWARP driver (nes)
---------------------------------------------------------------
What: /sys/class/infiniband/nesX/hw_rev
What: /sys/class/infiniband/nesX/hca_type
What: /sys/class/infiniband/nesX/board_id
Date: Feb, 2008
KernelVersion: v2.6.25
Contact: linux-rdma@vger.kernel.org
Description:
hw_rev: (RO) Hardware revision number
hca_type: (RO) Host Channel Adapter type (NEX020)
board_id: (RO) Manufacturing board id
sysfs interface for Chelsio T4/T5 RDMA driver (cxgb4)
-----------------------------------------------------

2
Documentation/ABI/stable/sysfs-class-rfkill
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@ -1,6 +1,6 @@
rfkill - radio frequency (RF) connector kill switch support
For details to this subsystem look at Documentation/rfkill.txt.
For details to this subsystem look at Documentation/driver-api/rfkill.rst.
For the deprecated /sys/class/rfkill/*/claim knobs of this interface look in
Documentation/ABI/removed/sysfs-class-rfkill.

2
Documentation/ABI/stable/sysfs-devices-node
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@ -61,7 +61,7 @@ Date: October 2002
Contact: Linux Memory Management list <linux-mm@kvack.org>
Description:
The node's hit/miss statistics, in units of pages.
See Documentation/numastat.txt
See Documentation/admin-guide/numastat.rst
What: /sys/devices/system/node/nodeX/distance
Date: October 2002

20
Documentation/ABI/stable/sysfs-driver-mlxreg-io
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@ -120,3 +120,23 @@ Description: These files show the system reset cause, as following: ComEx
the last reset cause.
The files are read only.
Date: June 2019
KernelVersion: 5.3
Contact: Vadim Pasternak <vadimpmellanox.com>
Description: These files show the system reset cause, as following:
COMEX thermal shutdown; wathchdog power off or reset was derived
by one of the next components: COMEX, switch board or by Small Form
Factor mezzanine, reset requested from ASIC, reset cuased by BIOS
reload. Value 1 in file means this is reset cause, 0 - otherwise.
Only one of the above causes could be 1 at the same time, representing
only last reset cause.
The files are read only.
What: /sys/devices/platform/mlxplat/mlxreg-io/hwmon/hwmon*/reset_comex_thermal
What: /sys/devices/platform/mlxplat/mlxreg-io/hwmon/hwmon*/reset_comex_wd
What: /sys/devices/platform/mlxplat/mlxreg-io/hwmon/hwmon*/reset_from_asic
What: /sys/devices/platform/mlxplat/mlxreg-io/hwmon/hwmon*/reset_reload_bios
What: /sys/devices/platform/mlxplat/mlxreg-io/hwmon/hwmon*/reset_sff_wd
What: /sys/devices/platform/mlxplat/mlxreg-io/hwmon/hwmon*/reset_swb_wd

2
Documentation/ABI/testing/procfs-diskstats
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@ -29,4 +29,4 @@ Description:
17 - sectors discarded
18 - time spent discarding
For more details refer to Documentation/iostats.txt
For more details refer to Documentation/admin-guide/iostats.rst

2
Documentation/ABI/testing/sysfs-block
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@ -15,7 +15,7 @@ Description:
9 - I/Os currently in progress
10 - time spent doing I/Os (ms)
11 - weighted time spent doing I/Os (ms)
For more details refer Documentation/iostats.txt
For more details refer Documentation/admin-guide/iostats.rst
What: /sys/block/<disk>/<part>/stat

2
Documentation/ABI/testing/sysfs-block-device
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@ -45,7 +45,7 @@ Description:
- Values below -2 are rejected with -EINVAL
For more information, see
Documentation/laptops/disk-shock-protection.txt
Documentation/admin-guide/laptops/disk-shock-protection.rst
What: /sys/block/*/device/ncq_prio_enable

32
Documentation/ABI/testing/sysfs-class-power
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@ -376,10 +376,42 @@ Description:
supply. Normally this is configured based on the type of
connection made (e.g. A configured SDP should output a maximum
of 500mA so the input current limit is set to the same value).
Use preferably input_power_limit, and for problems that can be
solved using power limit use input_current_limit.
Access: Read, Write
Valid values: Represented in microamps
What: /sys/class/power_supply/<supply_name>/input_voltage_limit
Date: May 2019
Contact: linux-pm@vger.kernel.org
Description:
This entry configures the incoming VBUS voltage limit currently
set in the supply. Normally this is configured based on
system-level knowledge or user input (e.g. This is part of the
Pixel C's thermal management strategy to effectively limit the
input power to 5V when the screen is on to meet Google's skin
temperature targets). Note that this feature should not be
used for safety critical things.
Use preferably input_power_limit, and for problems that can be
solved using power limit use input_voltage_limit.
Access: Read, Write
Valid values: Represented in microvolts
What: /sys/class/power_supply/<supply_name>/input_power_limit
Date: May 2019
Contact: linux-pm@vger.kernel.org
Description:
This entry configures the incoming power limit currently set
in the supply. Normally this is configured based on
system-level knowledge or user input. Use preferably this
feature to limit the incoming power and use current/voltage
limit only for problems that can be solved using power limit.
Access: Read, Write
Valid values: Represented in microwatts
What: /sys/class/power_supply/<supply_name>/online,
Date: May 2007
Contact: linux-pm@vger.kernel.org

30
Documentation/ABI/testing/sysfs-class-power-wilco 100644
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@ -0,0 +1,30 @@
What: /sys/class/power_supply/wilco-charger/charge_type
Date: April 2019
KernelVersion: 5.2
Description:
What charging algorithm to use:
Standard: Fully charges battery at a standard rate.
Adaptive: Battery settings adaptively optimized based on
typical battery usage pattern.
Fast: Battery charges over a shorter period.
Trickle: Extends battery lifespan, intended for users who
primarily use their Chromebook while connected to AC.
Custom: A low and high threshold percentage is specified.
Charging begins when level drops below
charge_control_start_threshold, and ceases when
level is above charge_control_end_threshold.
What: /sys/class/power_supply/wilco-charger/charge_control_start_threshold
Date: April 2019
KernelVersion: 5.2
Description:
Used when charge_type="Custom", as described above. Measured in
percentages. The valid range is [50, 95].
What: /sys/class/power_supply/wilco-charger/charge_control_end_threshold
Date: April 2019
KernelVersion: 5.2
Description:
Used when charge_type="Custom", as described above. Measured in
percentages. The valid range is [55, 100].

2
Documentation/ABI/testing/sysfs-class-powercap
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@ -5,7 +5,7 @@ Contact: linux-pm@vger.kernel.org
Description:
The powercap/ class sub directory belongs to the power cap
subsystem. Refer to
Documentation/power/powercap/powercap.txt for details.
Documentation/power/powercap/powercap.rst for details.
What: /sys/class/powercap/<control type>
Date: September 2013

2
Documentation/ABI/testing/sysfs-class-switchtec
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@ -1,6 +1,6 @@
switchtec - Microsemi Switchtec PCI Switch Management Endpoint
For details on this subsystem look at Documentation/switchtec.txt.
For details on this subsystem look at Documentation/driver-api/switchtec.rst.
What: /sys/class/switchtec
Date: 05-Jan-2017

4
Documentation/ABI/testing/sysfs-devices-system-cpu
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@ -34,7 +34,7 @@ Description: CPU topology files that describe kernel limits related to
present: cpus that have been identified as being present in
the system.
See Documentation/cputopology.txt for more information.
See Documentation/admin-guide/cputopology.rst for more information.
What: /sys/devices/system/cpu/probe
@ -103,7 +103,7 @@ Description: CPU topology files that describe a logical CPU's relationship
thread_siblings_list: human-readable list of cpu#'s hardware
threads within the same core as cpu#
See Documentation/cputopology.txt for more information.
See Documentation/admin-guide/cputopology.rst for more information.
What: /sys/devices/system/cpu/cpuidle/current_driver

2
Documentation/ABI/testing/sysfs-platform-asus-laptop
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@ -31,7 +31,7 @@ Description:
To control the LED display, use the following :
echo 0x0T000DDD > /sys/devices/platform/asus_laptop/
where T control the 3 letters display, and DDD the 3 digits display.
The DDD table can be found in Documentation/laptops/asus-laptop.txt
The DDD table can be found in Documentation/admin-guide/laptops/asus-laptop.rst
What: /sys/devices/platform/asus_laptop/bluetooth
Date: January 2007

10
Documentation/ABI/testing/sysfs-platform-asus-wmi
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@ -36,3 +36,13 @@ KernelVersion: 3.5
Contact: "AceLan Kao" <acelan.kao@canonical.com>
Description:
Resume on lid open. 1 means on, 0 means off.
What: /sys/devices/platform/<platform>/fan_boost_mode
Date: Sep 2019
KernelVersion: 5.3
Contact: "Yurii Pavlovskyi" <yurii.pavlovskyi@gmail.com>
Description:
Fan boost mode:
* 0 - normal,
* 1 - overboost,
* 2 - silent

4
Documentation/ABI/testing/sysfs-platform-i2c-demux-pinctrl
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@ -1,7 +1,7 @@
What: /sys/devices/platform/<i2c-demux-name>/available_masters
Date: January 2016
KernelVersion: 4.6
Contact: Wolfram Sang <wsa@the-dreams.de>
Contact: Wolfram Sang <wsa+renesas@sang-engineering.com>
Description:
Reading the file will give you a list of masters which can be
selected for a demultiplexed bus. The format is
@ -12,7 +12,7 @@ Description:
What: /sys/devices/platform/<i2c-demux-name>/current_master
Date: January 2016
KernelVersion: 4.6
Contact: Wolfram Sang <wsa@the-dreams.de>
Contact: Wolfram Sang <wsa+renesas@sang-engineering.com>
Description:
This file selects/shows the active I2C master for a demultiplexed
bus. It uses the <index> value from the file 'available_masters'.

0
Documentation/logo.txt → Documentation/COPYING-logo
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2
Documentation/DMA-API-HOWTO.txt
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@ -212,7 +212,7 @@ The standard 64-bit addressing device would do something like this::
If the device only supports 32-bit addressing for descriptors in the
coherent allocations, but supports full 64-bits for streaming mappings
it would look like this:
it would look like this::
if (dma_set_mask(dev, DMA_BIT_MASK(64))) {
dev_warn(dev, "mydev: No suitable DMA available\n");

15
Documentation/PCI/acpi-info.txt → Documentation/PCI/acpi-info.rst
View File

@ -1,4 +1,8 @@
ACPI considerations for PCI host bridges
.. SPDX-License-Identifier: GPL-2.0
========================================
ACPI considerations for PCI host bridges
========================================
The general rule is that the ACPI namespace should describe everything the
OS might use unless there's another way for the OS to find it [1, 2].
@ -131,12 +135,13 @@ address always corresponds to bus 0, even if the bus range below the bridge
[4] ACPI 6.2, sec 6.4.3.5.1, 2, 3, 4:
QWord/DWord/Word Address Space Descriptor (.1, .2, .3)
General Flags: Bit [0] Ignored
General Flags: Bit [0] Ignored
Extended Address Space Descriptor (.4)
General Flags: Bit [0] Consumer/Producer:
1This device consumes this resource
0This device produces and consumes this resource
General Flags: Bit [0] Consumer/Producer:
* 1 This device consumes this resource
* 0 This device produces and consumes this resource
[5] ACPI 6.2, sec 19.6.43:
ResourceUsage specifies whether the Memory range is consumed by

13
Documentation/PCI/endpoint/index.rst 100644
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@ -0,0 +1,13 @@
.. SPDX-License-Identifier: GPL-2.0
======================
PCI Endpoint Framework
======================
.. toctree::
:maxdepth: 2
pci-endpoint
pci-endpoint-cfs
pci-test-function
pci-test-howto

93
Documentation/PCI/endpoint/pci-endpoint-cfs.txt → Documentation/PCI/endpoint/pci-endpoint-cfs.rst
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@ -1,41 +1,51 @@
CONFIGURING PCI ENDPOINT USING CONFIGFS
Kishon Vijay Abraham I <kishon@ti.com>
.. SPDX-License-Identifier: GPL-2.0
=======================================
Configuring PCI Endpoint Using CONFIGFS
=======================================
:Author: Kishon Vijay Abraham I <kishon@ti.com>
The PCI Endpoint Core exposes configfs entry (pci_ep) to configure the
PCI endpoint function and to bind the endpoint function
with the endpoint controller. (For introducing other mechanisms to
configure the PCI Endpoint Function refer to [1]).
*) Mounting configfs
Mounting configfs
=================
The PCI Endpoint Core layer creates pci_ep directory in the mounted configfs
directory. configfs can be mounted using the following command.
directory. configfs can be mounted using the following command::
mount -t configfs none /sys/kernel/config
*) Directory Structure
Directory Structure
===================
The pci_ep configfs has two directories at its root: controllers and
functions. Every EPC device present in the system will have an entry in
the *controllers* directory and and every EPF driver present in the system
will have an entry in the *functions* directory.
::
/sys/kernel/config/pci_ep/
.. controllers/
.. functions/
/sys/kernel/config/pci_ep/
.. controllers/
.. functions/
*) Creating EPF Device
Creating EPF Device
===================
Every registered EPF driver will be listed in controllers directory. The
entries corresponding to EPF driver will be created by the EPF core.
::
/sys/kernel/config/pci_ep/functions/
.. <EPF Driver1>/
... <EPF Device 11>/
... <EPF Device 21>/
.. <EPF Driver2>/
... <EPF Device 12>/
... <EPF Device 22>/
/sys/kernel/config/pci_ep/functions/
.. <EPF Driver1>/
... <EPF Device 11>/
... <EPF Device 21>/
.. <EPF Driver2>/
... <EPF Device 12>/
... <EPF Device 22>/
In order to create a <EPF device> of the type probed by <EPF Driver>, the
user has to create a directory inside <EPF DriverN>.
@ -44,34 +54,37 @@ Every <EPF device> directory consists of the following entries that can be
used to configure the standard configuration header of the endpoint function.
(These entries are created by the framework when any new <EPF Device> is
created)
::
.. <EPF Driver1>/
... <EPF Device 11>/
... vendorid
... deviceid
... revid
... progif_code
... subclass_code
... baseclass_code
... cache_line_size
... subsys_vendor_id
... subsys_id
... interrupt_pin
.. <EPF Driver1>/
... <EPF Device 11>/
... vendorid
... deviceid
... revid
... progif_code
... subclass_code
... baseclass_code
... cache_line_size
... subsys_vendor_id
... subsys_id
... interrupt_pin
*) EPC Device
EPC Device
==========
Every registered EPC device will be listed in controllers directory. The
entries corresponding to EPC device will be created by the EPC core.
::
/sys/kernel/config/pci_ep/controllers/
.. <EPC Device1>/
... <Symlink EPF Device11>/
... <Symlink EPF Device12>/
... start
.. <EPC Device2>/
... <Symlink EPF Device21>/
... <Symlink EPF Device22>/
... start
/sys/kernel/config/pci_ep/controllers/
.. <EPC Device1>/
... <Symlink EPF Device11>/
... <Symlink EPF Device12>/
... start
.. <EPC Device2>/
... <Symlink EPF Device21>/
... <Symlink EPF Device22>/
... start
The <EPC Device> directory will have a list of symbolic links to
<EPF Device>. These symbolic links should be created by the user to
@ -81,7 +94,7 @@ The <EPC Device> directory will also have a *start* field. Once
"1" is written to this field, the endpoint device will be ready to
establish the link with the host. This is usually done after
all the EPF devices are created and linked with the EPC device.
::
| controllers/
| <Directory: EPC name>/
@ -102,4 +115,4 @@ all the EPF devices are created and linked with the EPC device.
| interrupt_pin
| function
[1] -> Documentation/PCI/endpoint/pci-endpoint.txt
[1] :doc:`pci-endpoint`

92
Documentation/PCI/endpoint/pci-endpoint.txt → Documentation/PCI/endpoint/pci-endpoint.rst
View File

@ -1,11 +1,13 @@
PCI ENDPOINT FRAMEWORK
Kishon Vijay Abraham I <kishon@ti.com>
.. SPDX-License-Identifier: GPL-2.0
:Author: Kishon Vijay Abraham I <kishon@ti.com>
This document is a guide to use the PCI Endpoint Framework in order to create
endpoint controller driver, endpoint function driver, and using configfs
interface to bind the function driver to the controller driver.
1. Introduction
Introduction
============
Linux has a comprehensive PCI subsystem to support PCI controllers that
operates in Root Complex mode. The subsystem has capability to scan PCI bus,
@ -19,26 +21,30 @@ add endpoint mode support in Linux. This will help to run Linux in an
EP system which can have a wide variety of use cases from testing or
validation, co-processor accelerator, etc.
2. PCI Endpoint Core
PCI Endpoint Core
=================
The PCI Endpoint Core layer comprises 3 components: the Endpoint Controller
library, the Endpoint Function library, and the configfs layer to bind the
endpoint function with the endpoint controller.
2.1 PCI Endpoint Controller(EPC) Library
PCI Endpoint Controller(EPC) Library
------------------------------------
The EPC library provides APIs to be used by the controller that can operate
in endpoint mode. It also provides APIs to be used by function driver/library
in order to implement a particular endpoint function.
2.1.1 APIs for the PCI controller Driver
APIs for the PCI controller Driver
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
This section lists the APIs that the PCI Endpoint core provides to be used
by the PCI controller driver.
*) devm_pci_epc_create()/pci_epc_create()
* devm_pci_epc_create()/pci_epc_create()
The PCI controller driver should implement the following ops:
* write_header: ops to populate configuration space header
* set_bar: ops to configure the BAR
* clear_bar: ops to reset the BAR
@ -51,110 +57,116 @@ by the PCI controller driver.
The PCI controller driver can then create a new EPC device by invoking
devm_pci_epc_create()/pci_epc_create().
*) devm_pci_epc_destroy()/pci_epc_destroy()
* devm_pci_epc_destroy()/pci_epc_destroy()
The PCI controller driver can destroy the EPC device created by either
devm_pci_epc_create() or pci_epc_create() using devm_pci_epc_destroy() or
pci_epc_destroy().
*) pci_epc_linkup()
* pci_epc_linkup()
In order to notify all the function devices that the EPC device to which
they are linked has established a link with the host, the PCI controller
driver should invoke pci_epc_linkup().
*) pci_epc_mem_init()
* pci_epc_mem_init()
Initialize the pci_epc_mem structure used for allocating EPC addr space.
*) pci_epc_mem_exit()
* pci_epc_mem_exit()
Cleanup the pci_epc_mem structure allocated during pci_epc_mem_init().
2.1.2 APIs for the PCI Endpoint Function Driver
APIs for the PCI Endpoint Function Driver
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
This section lists the APIs that the PCI Endpoint core provides to be used
by the PCI endpoint function driver.
*) pci_epc_write_header()
* pci_epc_write_header()
The PCI endpoint function driver should use pci_epc_write_header() to
write the standard configuration header to the endpoint controller.
*) pci_epc_set_bar()
* pci_epc_set_bar()
The PCI endpoint function driver should use pci_epc_set_bar() to configure
the Base Address Register in order for the host to assign PCI addr space.
Register space of the function driver is usually configured
using this API.
*) pci_epc_clear_bar()
* pci_epc_clear_bar()
The PCI endpoint function driver should use pci_epc_clear_bar() to reset
the BAR.
*) pci_epc_raise_irq()
* pci_epc_raise_irq()
The PCI endpoint function driver should use pci_epc_raise_irq() to raise
Legacy Interrupt, MSI or MSI-X Interrupt.
*) pci_epc_mem_alloc_addr()
* pci_epc_mem_alloc_addr()
The PCI endpoint function driver should use pci_epc_mem_alloc_addr(), to
allocate memory address from EPC addr space which is required to access
RC's buffer
*) pci_epc_mem_free_addr()
* pci_epc_mem_free_addr()
The PCI endpoint function driver should use pci_epc_mem_free_addr() to
free the memory space allocated using pci_epc_mem_alloc_addr().
2.1.3 Other APIs
Other APIs
~~~~~~~~~~
There are other APIs provided by the EPC library. These are used for binding
the EPF device with EPC device. pci-ep-cfs.c can be used as reference for
using these APIs.
*) pci_epc_get()
* pci_epc_get()
Get a reference to the PCI endpoint controller based on the device name of
the controller.
*) pci_epc_put()
* pci_epc_put()
Release the reference to the PCI endpoint controller obtained using
pci_epc_get()
*) pci_epc_add_epf()
* pci_epc_add_epf()
Add a PCI endpoint function to a PCI endpoint controller. A PCIe device
can have up to 8 functions according to the specification.
*) pci_epc_remove_epf()
* pci_epc_remove_epf()
Remove the PCI endpoint function from PCI endpoint controller.
*) pci_epc_start()
* pci_epc_start()
The PCI endpoint function driver should invoke pci_epc_start() once it
has configured the endpoint function and wants to start the PCI link.
*) pci_epc_stop()
* pci_epc_stop()
The PCI endpoint function driver should invoke pci_epc_stop() to stop
the PCI LINK.
2.2 PCI Endpoint Function(EPF) Library
PCI Endpoint Function(EPF) Library
----------------------------------
The EPF library provides APIs to be used by the function driver and the EPC
library to provide endpoint mode functionality.
2.2.1 APIs for the PCI Endpoint Function Driver
APIs for the PCI Endpoint Function Driver
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
This section lists the APIs that the PCI Endpoint core provides to be used
by the PCI endpoint function driver.
*) pci_epf_register_driver()
* pci_epf_register_driver()
The PCI Endpoint Function driver should implement the following ops:
* bind: ops to perform when a EPC device has been bound to EPF device
@ -166,50 +178,54 @@ by the PCI endpoint function driver.
The PCI Function driver can then register the PCI EPF driver by using
pci_epf_register_driver().
*) pci_epf_unregister_driver()
* pci_epf_unregister_driver()
The PCI Function driver can unregister the PCI EPF driver by using
pci_epf_unregister_driver().
*) pci_epf_alloc_space()
* pci_epf_alloc_space()
The PCI Function driver can allocate space for a particular BAR using
pci_epf_alloc_space().
*) pci_epf_free_space()
* pci_epf_free_space()
The PCI Function driver can free the allocated space
(using pci_epf_alloc_space) by invoking pci_epf_free_space().
2.2.2 APIs for the PCI Endpoint Controller Library
APIs for the PCI Endpoint Controller Library
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
This section lists the APIs that the PCI Endpoint core provides to be used
by the PCI endpoint controller library.
*) pci_epf_linkup()
* pci_epf_linkup()
The PCI endpoint controller library invokes pci_epf_linkup() when the
EPC device has established the connection to the host.
2.2.2 Other APIs
Other APIs
~~~~~~~~~~
There are other APIs provided by the EPF library. These are used to notify
the function driver when the EPF device is bound to the EPC device.
pci-ep-cfs.c can be used as reference for using these APIs.
*) pci_epf_create()
* pci_epf_create()
Create a new PCI EPF device by passing the name of the PCI EPF device.
This name will be used to bind the the EPF device to a EPF driver.
*) pci_epf_destroy()
* pci_epf_destroy()
Destroy the created PCI EPF device.
*) pci_epf_bind()
* pci_epf_bind()
pci_epf_bind() should be invoked when the EPF device has been bound to
a EPC device.
*) pci_epf_unbind()
* pci_epf_unbind()
pci_epf_unbind() should be invoked when the binding between EPC device
and EPF device is lost.

82
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@ -1,5 +1,10 @@
PCI TEST
Kishon Vijay Abraham I <kishon@ti.com>
.. SPDX-License-Identifier: GPL-2.0
=================
PCI Test Function
=================
:Author: Kishon Vijay Abraham I <kishon@ti.com>
Traditionally PCI RC has always been validated by using standard
PCI cards like ethernet PCI cards or USB PCI cards or SATA PCI cards.
@ -23,65 +28,76 @@ The PCI endpoint test device has the following registers:
8) PCI_ENDPOINT_TEST_IRQ_TYPE
9) PCI_ENDPOINT_TEST_IRQ_NUMBER
*) PCI_ENDPOINT_TEST_MAGIC
* PCI_ENDPOINT_TEST_MAGIC
This register will be used to test BAR0. A known pattern will be written
and read back from MAGIC register to verify BAR0.
*) PCI_ENDPOINT_TEST_COMMAND:
* PCI_ENDPOINT_TEST_COMMAND
This register will be used by the host driver to indicate the function
that the endpoint device must perform.
Bitfield Description:
Bit 0 : raise legacy IRQ
Bit 1 : raise MSI IRQ
Bit 2 : raise MSI-X IRQ
Bit 3 : read command (read data from RC buffer)
Bit 4 : write command (write data to RC buffer)
Bit 5 : copy command (copy data from one RC buffer to another
RC buffer)
======== ================================================================
Bitfield Description
======== ================================================================
Bit 0 raise legacy IRQ
Bit 1 raise MSI IRQ
Bit 2 raise MSI-X IRQ
Bit 3 read command (read data from RC buffer)
Bit 4 write command (write data to RC buffer)
Bit 5 copy command (copy data from one RC buffer to another RC buffer)
======== ================================================================
*) PCI_ENDPOINT_TEST_STATUS
* PCI_ENDPOINT_TEST_STATUS
This register reflects the status of the PCI endpoint device.
Bitfield Description:
Bit 0 : read success
Bit 1 : read fail
Bit 2 : write success
Bit 3 : write fail
Bit 4 : copy success
Bit 5 : copy fail
Bit 6 : IRQ raised
Bit 7 : source address is invalid
Bit 8 : destination address is invalid
======== ==============================
Bitfield Description
======== ==============================
Bit 0 read success
Bit 1 read fail
Bit 2 write success
Bit 3 write fail
Bit 4 copy success
Bit 5 copy fail
Bit 6 IRQ raised
Bit 7 source address is invalid
Bit 8 destination address is invalid
======== ==============================
*) PCI_ENDPOINT_TEST_SRC_ADDR
* PCI_ENDPOINT_TEST_SRC_ADDR
This register contains the source address (RC buffer address) for the
COPY/READ command.
*) PCI_ENDPOINT_TEST_DST_ADDR
* PCI_ENDPOINT_TEST_DST_ADDR
This register contains the destination address (RC buffer address) for
the COPY/WRITE command.
*) PCI_ENDPOINT_TEST_IRQ_TYPE
* PCI_ENDPOINT_TEST_IRQ_TYPE
This register contains the interrupt type (Legacy/MSI) triggered
for the READ/WRITE/COPY and raise IRQ (Legacy/MSI) commands.
Possible types:
- Legacy : 0
- MSI : 1
- MSI-X : 2
*) PCI_ENDPOINT_TEST_IRQ_NUMBER
====== ==
Legacy 0
MSI 1
MSI-X 2
====== ==
* PCI_ENDPOINT_TEST_IRQ_NUMBER
This register contains the triggered ID interrupt.
Admissible values:
- Legacy : 0
- MSI : [1 .. 32]
- MSI-X : [1 .. 2048]
====== ===========
Legacy 0
MSI [1 .. 32]
MSI-X [1 .. 2048]
====== ===========

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@ -1,38 +1,51 @@
PCI TEST USERGUIDE
Kishon Vijay Abraham I <kishon@ti.com>
.. SPDX-License-Identifier: GPL-2.0
===================
PCI Test User Guide
===================
:Author: Kishon Vijay Abraham I <kishon@ti.com>
This document is a guide to help users use pci-epf-test function driver
and pci_endpoint_test host driver for testing PCI. The list of steps to
be followed in the host side and EP side is given below.
1. Endpoint Device
Endpoint Device
===============
1.1 Endpoint Controller Devices
Endpoint Controller Devices
---------------------------
To find the list of endpoint controller devices in the system:
To find the list of endpoint controller devices in the system::
# ls /sys/class/pci_epc/
51000000.pcie_ep
If PCI_ENDPOINT_CONFIGFS is enabled
If PCI_ENDPOINT_CONFIGFS is enabled::
# ls /sys/kernel/config/pci_ep/controllers
51000000.pcie_ep
1.2 Endpoint Function Drivers
To find the list of endpoint function drivers in the system:
Endpoint Function Drivers
-------------------------
To find the list of endpoint function drivers in the system::
# ls /sys/bus/pci-epf/drivers
pci_epf_test
If PCI_ENDPOINT_CONFIGFS is enabled
If PCI_ENDPOINT_CONFIGFS is enabled::
# ls /sys/kernel/config/pci_ep/functions
pci_epf_test
1.3 Creating pci-epf-test Device
Creating pci-epf-test Device
----------------------------
PCI endpoint function device can be created using the configfs. To create
pci-epf-test device, the following commands can be used
pci-epf-test device, the following commands can be used::
# mount -t configfs none /sys/kernel/config
# cd /sys/kernel/config/pci_ep/
@ -42,7 +55,7 @@ The "mkdir func1" above creates the pci-epf-test function device that will
be probed by pci_epf_test driver.
The PCI endpoint framework populates the directory with the following
configurable fields.
configurable fields::
# ls functions/pci_epf_test/func1
baseclass_code interrupt_pin progif_code subsys_id
@ -51,67 +64,83 @@ configurable fields.
The PCI endpoint function driver populates these entries with default values
when the device is bound to the driver. The pci-epf-test driver populates
vendorid with 0xffff and interrupt_pin with 0x0001
vendorid with 0xffff and interrupt_pin with 0x0001::
# cat functions/pci_epf_test/func1/vendorid
0xffff
# cat functions/pci_epf_test/func1/interrupt_pin
0x0001
1.4 Configuring pci-epf-test Device
Configuring pci-epf-test Device
-------------------------------
The user can configure the pci-epf-test device using configfs entry. In order
to change the vendorid and the number of MSI interrupts used by the function
device, the following commands can be used.
device, the following commands can be used::
# echo 0x104c > functions/pci_epf_test/func1/vendorid
# echo 0xb500 > functions/pci_epf_test/func1/deviceid
# echo 16 > functions/pci_epf_test/func1/msi_interrupts
# echo 8 > functions/pci_epf_test/func1/msix_interrupts
1.5 Binding pci-epf-test Device to EP Controller
Binding pci-epf-test Device to EP Controller
--------------------------------------------
In order for the endpoint function device to be useful, it has to be bound to
a PCI endpoint controller driver. Use the configfs to bind the function
device to one of the controller driver present in the system.
device to one of the controller driver present in the system::
# ln -s functions/pci_epf_test/func1 controllers/51000000.pcie_ep/
Once the above step is completed, the PCI endpoint is ready to establish a link
with the host.
1.6 Start the Link
Start the Link
--------------
In order for the endpoint device to establish a link with the host, the _start_
field should be populated with '1'.
field should be populated with '1'::
# echo 1 > controllers/51000000.pcie_ep/start
2. RootComplex Device
2.1 lspci Output
RootComplex Device
==================
Note that the devices listed here correspond to the value populated in 1.4 above
lspci Output
------------
Note that the devices listed here correspond to the value populated in 1.4
above::
00:00.0 PCI bridge: Texas Instruments Device 8888 (rev 01)
01:00.0 Unassigned class [ff00]: Texas Instruments Device b500
2.2 Using Endpoint Test function Device
Using Endpoint Test function Device
-----------------------------------
pcitest.sh added in tools/pci/ can be used to run all the default PCI endpoint
tests. To compile this tool the following commands should be used:
tests. To compile this tool the following commands should be used::
# cd <kernel-dir>
# make -C tools/pci
or if you desire to compile and install in your system:
or if you desire to compile and install in your system::
# cd <kernel-dir>
# make -C tools/pci install
The tool and script will be located in <rootfs>/usr/bin/
2.2.1 pcitest.sh Output
pcitest.sh Output
~~~~~~~~~~~~~~~~~
::
# pcitest.sh
BAR tests

18
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View File

@ -0,0 +1,18 @@
.. SPDX-License-Identifier: GPL-2.0
=======================
Linux PCI Bus Subsystem
=======================
.. toctree::
:maxdepth: 2
:numbered:
pci
picebus-howto
pci-iov-howto
msi-howto
acpi-info
pci-error-recovery
pcieaer-howto
endpoint/index

85
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@ -1,13 +1,16 @@
The MSI Driver Guide HOWTO
Tom L Nguyen tom.l.nguyen@intel.com
10/03/2003
Revised Feb 12, 2004 by Martine Silbermann
email: Martine.Silbermann@hp.com
Revised Jun 25, 2004 by Tom L Nguyen
Revised Jul 9, 2008 by Matthew Wilcox <willy@linux.intel.com>
Copyright 2003, 2008 Intel Corporation
.. SPDX-License-Identifier: GPL-2.0
.. include:: <isonum.txt>
1. About this guide
==========================
The MSI Driver Guide HOWTO
==========================
:Authors: Tom L Nguyen; Martine Silbermann; Matthew Wilcox
:Copyright: 2003, 2008 Intel Corporation
About this guide
================
This guide describes the basics of Message Signaled Interrupts (MSIs),
the advantages of using MSI over traditional interrupt mechanisms, how
@ -15,7 +18,8 @@ to change your driver to use MSI or MSI-X and some basic diagnostics to
try if a device doesn't support MSIs.
2. What are MSIs?
What are MSIs?
==============
A Message Signaled Interrupt is a write from the device to a special
address which causes an interrupt to be received by the CPU.
@ -29,7 +33,8 @@ Devices may support both MSI and MSI-X, but only one can be enabled at
a time.
3. Why use MSIs?
Why use MSIs?
=============
There are three reasons why using MSIs can give an advantage over
traditional pin-based interrupts.
@ -61,14 +66,16 @@ Other possible designs include giving one interrupt to each packet queue
in a network card or each port in a storage controller.
4. How to use MSIs
How to use MSIs
===============
PCI devices are initialised to use pin-based interrupts. The device
driver has to set up the device to use MSI or MSI-X. Not all machines
support MSIs correctly, and for those machines, the APIs described below
will simply fail and the device will continue to use pin-based interrupts.
4.1 Include kernel support for MSIs
Include kernel support for MSIs
-------------------------------
To support MSI or MSI-X, the kernel must be built with the CONFIG_PCI_MSI
option enabled. This option is only available on some architectures,
@ -76,14 +83,15 @@ and it may depend on some other options also being set. For example,
on x86, you must also enable X86_UP_APIC or SMP in order to see the
CONFIG_PCI_MSI option.
4.2 Using MSI
Using MSI
---------
Most of the hard work is done for the driver in the PCI layer. The driver
simply has to request that the PCI layer set up the MSI capability for this
device.
To automatically use MSI or MSI-X interrupt vectors, use the following
function:
function::
int pci_alloc_irq_vectors(struct pci_dev *dev, unsigned int min_vecs,
unsigned int max_vecs, unsigned int flags);
@ -101,12 +109,12 @@ any possible kind of interrupt. If the PCI_IRQ_AFFINITY flag is set,
pci_alloc_irq_vectors() will spread the interrupts around the available CPUs.
To get the Linux IRQ numbers passed to request_irq() and free_irq() and the
vectors, use the following function:
vectors, use the following function::
int pci_irq_vector(struct pci_dev *dev, unsigned int nr);
Any allocated resources should be freed before removing the device using
the following function:
the following function::
void pci_free_irq_vectors(struct pci_dev *dev);
@ -126,7 +134,7 @@ The typical usage of MSI or MSI-X interrupts is to allocate as many vectors
as possible, likely up to the limit supported by the device. If nvec is
larger than the number supported by the device it will automatically be
capped to the supported limit, so there is no need to query the number of
vectors supported beforehand:
vectors supported beforehand::
nvec = pci_alloc_irq_vectors(pdev, 1, nvec, PCI_IRQ_ALL_TYPES)
if (nvec < 0)
@ -135,7 +143,7 @@ vectors supported beforehand:
If a driver is unable or unwilling to deal with a variable number of MSI
interrupts it can request a particular number of interrupts by passing that
number to pci_alloc_irq_vectors() function as both 'min_vecs' and
'max_vecs' parameters:
'max_vecs' parameters::
ret = pci_alloc_irq_vectors(pdev, nvec, nvec, PCI_IRQ_ALL_TYPES);
if (ret < 0)
@ -143,23 +151,24 @@ number to pci_alloc_irq_vectors() function as both 'min_vecs' and
The most notorious example of the request type described above is enabling
the single MSI mode for a device. It could be done by passing two 1s as
'min_vecs' and 'max_vecs':
'min_vecs' and 'max_vecs'::
ret = pci_alloc_irq_vectors(pdev, 1, 1, PCI_IRQ_ALL_TYPES);
if (ret < 0)
goto out_err;
Some devices might not support using legacy line interrupts, in which case
the driver can specify that only MSI or MSI-X is acceptable:
the driver can specify that only MSI or MSI-X is acceptable::
nvec = pci_alloc_irq_vectors(pdev, 1, nvec, PCI_IRQ_MSI | PCI_IRQ_MSIX);
if (nvec < 0)
goto out_err;
4.3 Legacy APIs
Legacy APIs
-----------
The following old APIs to enable and disable MSI or MSI-X interrupts should
not be used in new code:
not be used in new code::
pci_enable_msi() /* deprecated */
pci_disable_msi() /* deprecated */
@ -174,9 +183,11 @@ number of vectors. If you have a legitimate special use case for the count
of vectors we might have to revisit that decision and add a
pci_nr_irq_vectors() helper that handles MSI and MSI-X transparently.
4.4 Considerations when using MSIs
Considerations when using MSIs
------------------------------
4.4.1 Spinlocks
Spinlocks
~~~~~~~~~
Most device drivers have a per-device spinlock which is taken in the
interrupt handler. With pin-based interrupts or a single MSI, it is not
@ -188,7 +199,8 @@ acquire the spinlock. Such deadlocks can be avoided by using
spin_lock_irqsave() or spin_lock_irq() which disable local interrupts
and acquire the lock (see Documentation/kernel-hacking/locking.rst).
4.5 How to tell whether MSI/MSI-X is enabled on a device
How to tell whether MSI/MSI-X is enabled on a device
----------------------------------------------------
Using 'lspci -v' (as root) may show some devices with "MSI", "Message
Signalled Interrupts" or "MSI-X" capabilities. Each of these capabilities
@ -196,7 +208,8 @@ has an 'Enable' flag which is followed with either "+" (enabled)
or "-" (disabled).
5. MSI quirks
MSI quirks
==========
Several PCI chipsets or devices are known not to support MSIs.
The PCI stack provides three ways to disable MSIs:
@ -205,7 +218,8 @@ The PCI stack provides three ways to disable MSIs:
2. on all devices behind a specific bridge
3. on a single device
5.1. Disabling MSIs globally
Disabling MSIs globally
-----------------------
Some host chipsets simply don't support MSIs properly. If we're
lucky, the manufacturer knows this and has indicated it in the ACPI
@ -219,7 +233,8 @@ on the kernel command line to disable MSIs on all devices. It would be
in your best interests to report the problem to linux-pci@vger.kernel.org
including a full 'lspci -v' so we can add the quirks to the kernel.
5.2. Disabling MSIs below a bridge
Disabling MSIs below a bridge
-----------------------------
Some PCI bridges are not able to route MSIs between busses properly.
In this case, MSIs must be disabled on all devices behind the bridge.
@ -230,7 +245,7 @@ as the nVidia nForce and Serverworks HT2000). As with host chipsets,
Linux mostly knows about them and automatically enables MSIs if it can.
If you have a bridge unknown to Linux, you can enable
MSIs in configuration space using whatever method you know works, then
enable MSIs on that bridge by doing:
enable MSIs on that bridge by doing::
echo 1 > /sys/bus/pci/devices/$bridge/msi_bus
@ -244,7 +259,8 @@ below this bridge.
Again, please notify linux-pci@vger.kernel.org of any bridges that need
special handling.
5.3. Disabling MSIs on a single device
Disabling MSIs on a single device
---------------------------------
Some devices are known to have faulty MSI implementations. Usually this
is handled in the individual device driver, but occasionally it's necessary
@ -252,7 +268,8 @@ to handle this with a quirk. Some drivers have an option to disable use
of MSI. While this is a convenient workaround for the driver author,
it is not good practice, and should not be emulated.
5.4. Finding why MSIs are disabled on a device
Finding why MSIs are disabled on a device
-----------------------------------------
From the above three sections, you can see that there are many reasons
why MSIs may not be enabled for a given device. Your first step should
@ -260,8 +277,8 @@ be to examine your dmesg carefully to determine whether MSIs are enabled
for your machine. You should also check your .config to be sure you
have enabled CONFIG_PCI_MSI.
Then, 'lspci -t' gives the list of bridges above a device. Reading
/sys/bus/pci/devices/*/msi_bus will tell you whether MSIs are enabled (1)
Then, 'lspci -t' gives the list of bridges above a device. Reading
`/sys/bus/pci/devices/*/msi_bus` will tell you whether MSIs are enabled (1)
or disabled (0). If 0 is found in any of the msi_bus files belonging
to bridges between the PCI root and the device, MSIs are disabled.

271
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@ -1,12 +1,13 @@
.. SPDX-License-Identifier: GPL-2.0
PCI Error Recovery
------------------
February 2, 2006
==================
PCI Error Recovery
==================
Current document maintainer:
Linas Vepstas <linasvepstas@gmail.com>
updated by Richard Lary <rlary@us.ibm.com>
and Mike Mason <mmlnx@us.ibm.com> on 27-Jul-2009
:Authors: - Linas Vepstas <linasvepstas@gmail.com>
- Richard Lary <rlary@us.ibm.com>
- Mike Mason <mmlnx@us.ibm.com>
Many PCI bus controllers are able to detect a variety of hardware
@ -63,7 +64,8 @@ mechanisms for dealing with SCSI bus errors and SCSI bus resets.
Detailed Design
---------------
===============
Design and implementation details below, based on a chain of
public email discussions with Ben Herrenschmidt, circa 5 April 2005.
@ -73,30 +75,33 @@ pci_driver. A driver that fails to provide the structure is "non-aware",
and the actual recovery steps taken are platform dependent. The
arch/powerpc implementation will simulate a PCI hotplug remove/add.
This structure has the form:
struct pci_error_handlers
{
int (*error_detected)(struct pci_dev *dev, enum pci_channel_state);
int (*mmio_enabled)(struct pci_dev *dev);
int (*slot_reset)(struct pci_dev *dev);
void (*resume)(struct pci_dev *dev);
};
This structure has the form::
The possible channel states are:
enum pci_channel_state {
pci_channel_io_normal, /* I/O channel is in normal state */
pci_channel_io_frozen, /* I/O to channel is blocked */
pci_channel_io_perm_failure, /* PCI card is dead */
};
struct pci_error_handlers
{
int (*error_detected)(struct pci_dev *dev, enum pci_channel_state);
int (*mmio_enabled)(struct pci_dev *dev);
int (*slot_reset)(struct pci_dev *dev);
void (*resume)(struct pci_dev *dev);
};
Possible return values are:
enum pci_ers_result {
PCI_ERS_RESULT_NONE, /* no result/none/not supported in device driver */
PCI_ERS_RESULT_CAN_RECOVER, /* Device driver can recover without slot reset */
PCI_ERS_RESULT_NEED_RESET, /* Device driver wants slot to be reset. */
PCI_ERS_RESULT_DISCONNECT, /* Device has completely failed, is unrecoverable */
PCI_ERS_RESULT_RECOVERED, /* Device driver is fully recovered and operational */
};
The possible channel states are::
enum pci_channel_state {
pci_channel_io_normal, /* I/O channel is in normal state */
pci_channel_io_frozen, /* I/O to channel is blocked */
pci_channel_io_perm_failure, /* PCI card is dead */
};
Possible return values are::
enum pci_ers_result {
PCI_ERS_RESULT_NONE, /* no result/none/not supported in device driver */
PCI_ERS_RESULT_CAN_RECOVER, /* Device driver can recover without slot reset */
PCI_ERS_RESULT_NEED_RESET, /* Device driver wants slot to be reset. */
PCI_ERS_RESULT_DISCONNECT, /* Device has completely failed, is unrecoverable */
PCI_ERS_RESULT_RECOVERED, /* Device driver is fully recovered and operational */
};
A driver does not have to implement all of these callbacks; however,
if it implements any, it must implement error_detected(). If a callback
@ -134,16 +139,17 @@ shouldn't do any new IOs. Called in task context. This is sort of a
All drivers participating in this system must implement this call.
The driver must return one of the following result codes:
- PCI_ERS_RESULT_CAN_RECOVER:
Driver returns this if it thinks it might be able to recover
the HW by just banging IOs or if it wants to be given
a chance to extract some diagnostic information (see
mmio_enable, below).
- PCI_ERS_RESULT_NEED_RESET:
Driver returns this if it can't recover without a
slot reset.
- PCI_ERS_RESULT_DISCONNECT:
Driver returns this if it doesn't want to recover at all.
- PCI_ERS_RESULT_CAN_RECOVER
Driver returns this if it thinks it might be able to recover
the HW by just banging IOs or if it wants to be given
a chance to extract some diagnostic information (see
mmio_enable, below).
- PCI_ERS_RESULT_NEED_RESET
Driver returns this if it can't recover without a
slot reset.
- PCI_ERS_RESULT_DISCONNECT
Driver returns this if it doesn't want to recover at all.
The next step taken will depend on the result codes returned by the
drivers.
@ -159,25 +165,27 @@ then recovery proceeds to STEP 4 (Slot Reset).
If the platform is unable to recover the slot, the next step
is STEP 6 (Permanent Failure).
>>> The current powerpc implementation assumes that a device driver will
>>> *not* schedule or semaphore in this routine; the current powerpc
>>> implementation uses one kernel thread to notify all devices;
>>> thus, if one device sleeps/schedules, all devices are affected.
>>> Doing better requires complex multi-threaded logic in the error
>>> recovery implementation (e.g. waiting for all notification threads
>>> to "join" before proceeding with recovery.) This seems excessively
>>> complex and not worth implementing.
.. note::
>>> The current powerpc implementation doesn't much care if the device
>>> attempts I/O at this point, or not. I/O's will fail, returning
>>> a value of 0xff on read, and writes will be dropped. If more than
>>> EEH_MAX_FAILS I/O's are attempted to a frozen adapter, EEH
>>> assumes that the device driver has gone into an infinite loop
>>> and prints an error to syslog. A reboot is then required to
>>> get the device working again.
The current powerpc implementation assumes that a device driver will
*not* schedule or semaphore in this routine; the current powerpc
implementation uses one kernel thread to notify all devices;
thus, if one device sleeps/schedules, all devices are affected.
Doing better requires complex multi-threaded logic in the error
recovery implementation (e.g. waiting for all notification threads
to "join" before proceeding with recovery.) This seems excessively
complex and not worth implementing.
The current powerpc implementation doesn't much care if the device
attempts I/O at this point, or not. I/O's will fail, returning
a value of 0xff on read, and writes will be dropped. If more than
EEH_MAX_FAILS I/O's are attempted to a frozen adapter, EEH
assumes that the device driver has gone into an infinite loop
and prints an error to syslog. A reboot is then required to
get the device working again.
STEP 2: MMIO Enabled
-------------------
--------------------
The platform re-enables MMIO to the device (but typically not the
DMA), and then calls the mmio_enabled() callback on all affected
device drivers.
@ -192,34 +200,36 @@ link reset was performed by the HW. If the platform can't just re-enable IOs
without a slot reset or a link reset, it will not call this callback, and
instead will have gone directly to STEP 3 (Link Reset) or STEP 4 (Slot Reset)
>>> The following is proposed; no platform implements this yet:
>>> Proposal: All I/O's should be done _synchronously_ from within
>>> this callback, errors triggered by them will be returned via
>>> the normal pci_check_whatever() API, no new error_detected()
>>> callback will be issued due to an error happening here. However,
>>> such an error might cause IOs to be re-blocked for the whole
>>> segment, and thus invalidate the recovery that other devices
>>> on the same segment might have done, forcing the whole segment
>>> into one of the next states, that is, link reset or slot reset.
.. note::
The following is proposed; no platform implements this yet:
Proposal: All I/O's should be done _synchronously_ from within
this callback, errors triggered by them will be returned via
the normal pci_check_whatever() API, no new error_detected()
callback will be issued due to an error happening here. However,
such an error might cause IOs to be re-blocked for the whole
segment, and thus invalidate the recovery that other devices
on the same segment might have done, forcing the whole segment
into one of the next states, that is, link reset or slot reset.
The driver should return one of the following result codes:
- PCI_ERS_RESULT_RECOVERED
Driver returns this if it thinks the device is fully
functional and thinks it is ready to start
normal driver operations again. There is no
guarantee that the driver will actually be
allowed to proceed, as another driver on the
same segment might have failed and thus triggered a
slot reset on platforms that support it.
- PCI_ERS_RESULT_RECOVERED
Driver returns this if it thinks the device is fully
functional and thinks it is ready to start
normal driver operations again. There is no
guarantee that the driver will actually be
allowed to proceed, as another driver on the
same segment might have failed and thus triggered a
slot reset on platforms that support it.
- PCI_ERS_RESULT_NEED_RESET
Driver returns this if it thinks the device is not
recoverable in its current state and it needs a slot
reset to proceed.
- PCI_ERS_RESULT_NEED_RESET
Driver returns this if it thinks the device is not
recoverable in its current state and it needs a slot
reset to proceed.
- PCI_ERS_RESULT_DISCONNECT
Same as above. Total failure, no recovery even after
reset driver dead. (To be defined more precisely)
- PCI_ERS_RESULT_DISCONNECT
Same as above. Total failure, no recovery even after
reset driver dead. (To be defined more precisely)
The next step taken depends on the results returned by the drivers.
If all drivers returned PCI_ERS_RESULT_RECOVERED, then the platform
@ -293,31 +303,33 @@ device will be considered "dead" in this case.
Drivers for multi-function cards will need to coordinate among
themselves as to which driver instance will perform any "one-shot"
or global device initialization. For example, the Symbios sym53cxx2
driver performs device init only from PCI function 0:
driver performs device init only from PCI function 0::
+ if (PCI_FUNC(pdev->devfn) == 0)
+ sym_reset_scsi_bus(np, 0);
+ if (PCI_FUNC(pdev->devfn) == 0)
+ sym_reset_scsi_bus(np, 0);
Result codes:
- PCI_ERS_RESULT_DISCONNECT
Same as above.
Result codes:
- PCI_ERS_RESULT_DISCONNECT
Same as above.
Drivers for PCI Express cards that require a fundamental reset must
set the needs_freset bit in the pci_dev structure in their probe function.
For example, the QLogic qla2xxx driver sets the needs_freset bit for certain
PCI card types:
PCI card types::
+ /* Set EEH reset type to fundamental if required by hba */
+ if (IS_QLA24XX(ha) || IS_QLA25XX(ha) || IS_QLA81XX(ha))
+ pdev->needs_freset = 1;
+
+ /* Set EEH reset type to fundamental if required by hba */
+ if (IS_QLA24XX(ha) || IS_QLA25XX(ha) || IS_QLA81XX(ha))
+ pdev->needs_freset = 1;
+
Platform proceeds either to STEP 5 (Resume Operations) or STEP 6 (Permanent
Failure).
>>> The current powerpc implementation does not try a power-cycle
>>> reset if the driver returned PCI_ERS_RESULT_DISCONNECT.
>>> However, it probably should.
.. note::
The current powerpc implementation does not try a power-cycle
reset if the driver returned PCI_ERS_RESULT_DISCONNECT.
However, it probably should.
STEP 5: Resume Operations
@ -370,44 +382,43 @@ The current policy is to turn this into a platform policy.
That is, the recovery API only requires that:
- There is no guarantee that interrupt delivery can proceed from any
device on the segment starting from the error detection and until the
slot_reset callback is called, at which point interrupts are expected
to be fully operational.
device on the segment starting from the error detection and until the
slot_reset callback is called, at which point interrupts are expected
to be fully operational.
- There is no guarantee that interrupt delivery is stopped, that is,
a driver that gets an interrupt after detecting an error, or that detects
an error within the interrupt handler such that it prevents proper
ack'ing of the interrupt (and thus removal of the source) should just
return IRQ_NOTHANDLED. It's up to the platform to deal with that
condition, typically by masking the IRQ source during the duration of
the error handling. It is expected that the platform "knows" which
interrupts are routed to error-management capable slots and can deal
with temporarily disabling that IRQ number during error processing (this
isn't terribly complex). That means some IRQ latency for other devices
sharing the interrupt, but there is simply no other way. High end
platforms aren't supposed to share interrupts between many devices
anyway :)
a driver that gets an interrupt after detecting an error, or that detects
an error within the interrupt handler such that it prevents proper
ack'ing of the interrupt (and thus removal of the source) should just
return IRQ_NOTHANDLED. It's up to the platform to deal with that
condition, typically by masking the IRQ source during the duration of
the error handling. It is expected that the platform "knows" which
interrupts are routed to error-management capable slots and can deal
with temporarily disabling that IRQ number during error processing (this
isn't terribly complex). That means some IRQ latency for other devices
sharing the interrupt, but there is simply no other way. High end
platforms aren't supposed to share interrupts between many devices
anyway :)
>>> Implementation details for the powerpc platform are discussed in
>>> the file Documentation/powerpc/eeh-pci-error-recovery.txt
.. note::
>>> As of this writing, there is a growing list of device drivers with
>>> patches implementing error recovery. Not all of these patches are in
>>> mainline yet. These may be used as "examples":
>>>
>>> drivers/scsi/ipr
>>> drivers/scsi/sym53c8xx_2
>>> drivers/scsi/qla2xxx
>>> drivers/scsi/lpfc
>>> drivers/next/bnx2.c
>>> drivers/next/e100.c
>>> drivers/net/e1000
>>> drivers/net/e1000e
>>> drivers/net/ixgb
>>> drivers/net/ixgbe
>>> drivers/net/cxgb3
>>> drivers/net/s2io.c
>>> drivers/net/qlge
Implementation details for the powerpc platform are discussed in
the file Documentation/powerpc/eeh-pci-error-recovery.txt
The End
-------
As of this writing, there is a growing list of device drivers with
patches implementing error recovery. Not all of these patches are in
mainline yet. These may be used as "examples":
- drivers/scsi/ipr
- drivers/scsi/sym53c8xx_2
- drivers/scsi/qla2xxx
- drivers/scsi/lpfc
- drivers/next/bnx2.c
- drivers/next/e100.c
- drivers/net/e1000
- drivers/net/e1000e
- drivers/net/ixgb
- drivers/net/ixgbe
- drivers/net/cxgb3
- drivers/net/s2io.c
- drivers/net/qlge

175
Documentation/PCI/pci-iov-howto.txt → Documentation/PCI/pci-iov-howto.rst
View File

@ -1,14 +1,19 @@
PCI Express I/O Virtualization Howto
Copyright (C) 2009 Intel Corporation
Yu Zhao <yu.zhao@intel.com>
.. SPDX-License-Identifier: GPL-2.0
.. include:: <isonum.txt>
Update: November 2012
-- sysfs-based SRIOV enable-/disable-ment
Donald Dutile <ddutile@redhat.com>
====================================
PCI Express I/O Virtualization Howto
====================================
1. Overview
:Copyright: |copy| 2009 Intel Corporation
:Authors: - Yu Zhao <yu.zhao@intel.com>
- Donald Dutile <ddutile@redhat.com>
1.1 What is SR-IOV
Overview
========
What is SR-IOV
--------------
Single Root I/O Virtualization (SR-IOV) is a PCI Express Extended
capability which makes one physical device appear as multiple virtual
@ -23,9 +28,11 @@ Memory Space, which is used to map its register set. VF device driver
operates on the register set so it can be functional and appear as a
real existing PCI device.
2. User Guide
User Guide
==========
2.1 How can I enable SR-IOV capability
How can I enable SR-IOV capability
----------------------------------
Multiple methods are available for SR-IOV enablement.
In the first method, the device driver (PF driver) will control the
@ -43,105 +50,123 @@ checks, e.g., check numvfs == 0 if enabling VFs, ensure
numvfs <= totalvfs.
The second method is the recommended method for new/future VF devices.
2.2 How can I use the Virtual Functions
How can I use the Virtual Functions
-----------------------------------
The VF is treated as hot-plugged PCI devices in the kernel, so they
should be able to work in the same way as real PCI devices. The VF
requires device driver that is same as a normal PCI device's.
3. Developer Guide
Developer Guide
===============
3.1 SR-IOV API
SR-IOV API
----------
To enable SR-IOV capability:
(a) For the first method, in the driver:
(a) For the first method, in the driver::
int pci_enable_sriov(struct pci_dev *dev, int nr_virtfn);
'nr_virtfn' is number of VFs to be enabled.
(b) For the second method, from sysfs:
'nr_virtfn' is number of VFs to be enabled.
(b) For the second method, from sysfs::
echo 'nr_virtfn' > \
/sys/bus/pci/devices/<DOMAIN:BUS:DEVICE.FUNCTION>/sriov_numvfs
To disable SR-IOV capability:
(a) For the first method, in the driver:
(a) For the first method, in the driver::
void pci_disable_sriov(struct pci_dev *dev);
(b) For the second method, from sysfs:
(b) For the second method, from sysfs::
echo 0 > \
/sys/bus/pci/devices/<DOMAIN:BUS:DEVICE.FUNCTION>/sriov_numvfs
To enable auto probing VFs by a compatible driver on the host, run
command below before enabling SR-IOV capabilities. This is the
default behavior.
::
echo 1 > \
/sys/bus/pci/devices/<DOMAIN:BUS:DEVICE.FUNCTION>/sriov_drivers_autoprobe
To disable auto probing VFs by a compatible driver on the host, run
command below before enabling SR-IOV capabilities. Updating this
entry will not affect VFs which are already probed.
::
echo 0 > \
/sys/bus/pci/devices/<DOMAIN:BUS:DEVICE.FUNCTION>/sriov_drivers_autoprobe
3.2 Usage example
Usage example
-------------
Following piece of code illustrates the usage of the SR-IOV API.
::
static int dev_probe(struct pci_dev *dev, const struct pci_device_id *id)
{
pci_enable_sriov(dev, NR_VIRTFN);
static int dev_probe(struct pci_dev *dev, const struct pci_device_id *id)
{
pci_enable_sriov(dev, NR_VIRTFN);
...
return 0;
}
static void dev_remove(struct pci_dev *dev)
{
pci_disable_sriov(dev);
...
}
static int dev_suspend(struct pci_dev *dev, pm_message_t state)
{
...
return 0;
}
static int dev_resume(struct pci_dev *dev)
{
...
return 0;
}
static void dev_shutdown(struct pci_dev *dev)
{
...
}
static int dev_sriov_configure(struct pci_dev *dev, int numvfs)
{
if (numvfs > 0) {
...
pci_enable_sriov(dev, numvfs);
...
return numvfs;
}
if (numvfs == 0) {
....
pci_disable_sriov(dev);
...
return 0;
}
}
static struct pci_driver dev_driver = {
.name = "SR-IOV Physical Function driver",
.id_table = dev_id_table,
.probe = dev_probe,
.remove = dev_remove,
.suspend = dev_suspend,
.resume = dev_resume,
.shutdown = dev_shutdown,
.sriov_configure = dev_sriov_configure,
};
static void dev_remove(struct pci_dev *dev)
{
pci_disable_sriov(dev);
...
}
static int dev_suspend(struct pci_dev *dev, pm_message_t state)
{
...
return 0;
}
static int dev_resume(struct pci_dev *dev)
{
...
return 0;
}
static void dev_shutdown(struct pci_dev *dev)
{
...
}
static int dev_sriov_configure(struct pci_dev *dev, int numvfs)
{
if (numvfs > 0) {
...
pci_enable_sriov(dev, numvfs);
...
return numvfs;
}
if (numvfs == 0) {
....
pci_disable_sriov(dev);
...
return 0;
}
}
static struct pci_driver dev_driver = {
.name = "SR-IOV Physical Function driver",
.id_table = dev_id_table,
.probe = dev_probe,
.remove = dev_remove,
.suspend = dev_suspend,
.resume = dev_resume,
.shutdown = dev_shutdown,
.sriov_configure = dev_sriov_configure,
};

354
Documentation/PCI/pci.txt → Documentation/PCI/pci.rst
View File

@ -1,10 +1,12 @@
.. SPDX-License-Identifier: GPL-2.0
How To Write Linux PCI Drivers
==============================
How To Write Linux PCI Drivers
==============================
by Martin Mares <mj@ucw.cz> on 07-Feb-2000
updated by Grant Grundler <grundler@parisc-linux.org> on 23-Dec-2006
:Authors: - Martin Mares <mj@ucw.cz>
- Grant Grundler <grundler@parisc-linux.org>
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The world of PCI is vast and full of (mostly unpleasant) surprises.
Since each CPU architecture implements different chip-sets and PCI devices
have different requirements (erm, "features"), the result is the PCI support
@ -15,8 +17,7 @@ PCI device drivers.
A more complete resource is the third edition of "Linux Device Drivers"
by Jonathan Corbet, Alessandro Rubini, and Greg Kroah-Hartman.
LDD3 is available for free (under Creative Commons License) from:
http://lwn.net/Kernel/LDD3/
http://lwn.net/Kernel/LDD3/.
However, keep in mind that all documents are subject to "bit rot".
Refer to the source code if things are not working as described here.
@ -25,9 +26,8 @@ Please send questions/comments/patches about Linux PCI API to the
"Linux PCI" <linux-pci@atrey.karlin.mff.cuni.cz> mailing list.
0. Structure of PCI drivers
~~~~~~~~~~~~~~~~~~~~~~~~~~~
Structure of PCI drivers
========================
PCI drivers "discover" PCI devices in a system via pci_register_driver().
Actually, it's the other way around. When the PCI generic code discovers
a new device, the driver with a matching "description" will be notified.
@ -42,24 +42,25 @@ pointers and thus dictates the high level structure of a driver.
Once the driver knows about a PCI device and takes ownership, the
driver generally needs to perform the following initialization:
Enable the device
Request MMIO/IOP resources
Set the DMA mask size (for both coherent and streaming DMA)
Allocate and initialize shared control data (pci_allocate_coherent())
Access device configuration space (if needed)
Register IRQ handler (request_irq())
Initialize non-PCI (i.e. LAN/SCSI/etc parts of the chip)
Enable DMA/processing engines
- Enable the device
- Request MMIO/IOP resources
- Set the DMA mask size (for both coherent and streaming DMA)
- Allocate and initialize shared control data (pci_allocate_coherent())
- Access device configuration space (if needed)
- Register IRQ handler (request_irq())
- Initialize non-PCI (i.e. LAN/SCSI/etc parts of the chip)
- Enable DMA/processing engines
When done using the device, and perhaps the module needs to be unloaded,
the driver needs to take the follow steps:
Disable the device from generating IRQs
Release the IRQ (free_irq())
Stop all DMA activity
Release DMA buffers (both streaming and coherent)
Unregister from other subsystems (e.g. scsi or netdev)
Release MMIO/IOP resources
Disable the device
- Disable the device from generating IRQs
- Release the IRQ (free_irq())
- Stop all DMA activity
- Release DMA buffers (both streaming and coherent)
- Unregister from other subsystems (e.g. scsi or netdev)
- Release MMIO/IOP resources
- Disable the device
Most of these topics are covered in the following sections.
For the rest look at LDD3 or <linux/pci.h> .
@ -70,99 +71,38 @@ completely empty or just returning an appropriate error codes to avoid
lots of ifdefs in the drivers.
pci_register_driver() call
==========================
1. pci_register_driver() call
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
PCI device drivers call pci_register_driver() during their
PCI device drivers call ``pci_register_driver()`` during their
initialization with a pointer to a structure describing the driver
(struct pci_driver):
(``struct pci_driver``):
field name Description
---------- ------------------------------------------------------
id_table Pointer to table of device ID's the driver is
interested in. Most drivers should export this
table using MODULE_DEVICE_TABLE(pci,...).
.. kernel-doc:: include/linux/pci.h
:functions: pci_driver
probe This probing function gets called (during execution
of pci_register_driver() for already existing
devices or later if a new device gets inserted) for
all PCI devices which match the ID table and are not
"owned" by the other drivers yet. This function gets
passed a "struct pci_dev *" for each device whose
entry in the ID table matches the device. The probe
function returns zero when the driver chooses to
take "ownership" of the device or an error code
(negative number) otherwise.
The probe function always gets called from process
context, so it can sleep.
remove The remove() function gets called whenever a device
being handled by this driver is removed (either during
deregistration of the driver or when it's manually
pulled out of a hot-pluggable slot).
The remove function always gets called from process
context, so it can sleep.
suspend Put device into low power state.
suspend_late Put device into low power state.
resume_early Wake device from low power state.
resume Wake device from low power state.
(Please see Documentation/power/pci.txt for descriptions
of PCI Power Management and the related functions.)
shutdown Hook into reboot_notifier_list (kernel/sys.c).
Intended to stop any idling DMA operations.
Useful for enabling wake-on-lan (NIC) or changing
the power state of a device before reboot.
e.g. drivers/net/e100.c.
err_handler See Documentation/PCI/pci-error-recovery.txt
The ID table is an array of struct pci_device_id entries ending with an
The ID table is an array of ``struct pci_device_id`` entries ending with an
all-zero entry. Definitions with static const are generally preferred.
Each entry consists of:
.. kernel-doc:: include/linux/mod_devicetable.h
:functions: pci_device_id
vendor,device Vendor and device ID to match (or PCI_ANY_ID)
subvendor, Subsystem vendor and device ID to match (or PCI_ANY_ID)
subdevice,
class Device class, subclass, and "interface" to match.
See Appendix D of the PCI Local Bus Spec or
include/linux/pci_ids.h for a full list of classes.
Most drivers do not need to specify class/class_mask
as vendor/device is normally sufficient.
class_mask limit which sub-fields of the class field are compared.
See drivers/scsi/sym53c8xx_2/ for example of usage.
driver_data Data private to the driver.
Most drivers don't need to use driver_data field.
Best practice is to use driver_data as an index
into a static list of equivalent device types,
instead of using it as a pointer.
Most drivers only need PCI_DEVICE() or PCI_DEVICE_CLASS() to set up
Most drivers only need ``PCI_DEVICE()`` or ``PCI_DEVICE_CLASS()`` to set up
a pci_device_id table.
New PCI IDs may be added to a device driver pci_ids table at runtime
as shown below:
as shown below::
echo "vendor device subvendor subdevice class class_mask driver_data" > \
/sys/bus/pci/drivers/{driver}/new_id
echo "vendor device subvendor subdevice class class_mask driver_data" > \
/sys/bus/pci/drivers/{driver}/new_id
All fields are passed in as hexadecimal values (no leading 0x).
The vendor and device fields are mandatory, the others are optional. Users
need pass only as many optional fields as necessary:
o subvendor and subdevice fields default to PCI_ANY_ID (FFFFFFFF)
o class and classmask fields default to 0
o driver_data defaults to 0UL.
- subvendor and subdevice fields default to PCI_ANY_ID (FFFFFFFF)
- class and classmask fields default to 0
- driver_data defaults to 0UL.
Note that driver_data must match the value used by any of the pci_device_id
entries defined in the driver. This makes the driver_data field mandatory
@ -175,29 +115,31 @@ When the driver exits, it just calls pci_unregister_driver() and the PCI layer
automatically calls the remove hook for all devices handled by the driver.
1.1 "Attributes" for driver functions/data
"Attributes" for driver functions/data
--------------------------------------
Please mark the initialization and cleanup functions where appropriate
(the corresponding macros are defined in <linux/init.h>):
====== =================================================
__init Initialization code. Thrown away after the driver
initializes.
__exit Exit code. Ignored for non-modular drivers.
====== =================================================
Tips on when/where to use the above attributes:
o The module_init()/module_exit() functions (and all
- The module_init()/module_exit() functions (and all
initialization functions called _only_ from these)
should be marked __init/__exit.
o Do not mark the struct pci_driver.
- Do not mark the struct pci_driver.
o Do NOT mark a function if you are not sure which mark to use.
- Do NOT mark a function if you are not sure which mark to use.
Better to not mark the function than mark the function wrong.
2. How to find PCI devices manually
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
How to find PCI devices manually
================================
PCI drivers should have a really good reason for not using the
pci_register_driver() interface to search for PCI devices.
@ -207,17 +149,17 @@ E.g. combined serial/parallel port/floppy controller.
A manual search may be performed using the following constructs:
Searching by vendor and device ID:
Searching by vendor and device ID::
struct pci_dev *dev = NULL;
while (dev = pci_get_device(VENDOR_ID, DEVICE_ID, dev))
configure_device(dev);
Searching by class ID (iterate in a similar way):
Searching by class ID (iterate in a similar way)::
pci_get_class(CLASS_ID, dev)
Searching by both vendor/device and subsystem vendor/device ID:
Searching by both vendor/device and subsystem vendor/device ID::
pci_get_subsys(VENDOR_ID,DEVICE_ID, SUBSYS_VENDOR_ID, SUBSYS_DEVICE_ID, dev).
@ -230,21 +172,20 @@ the pci_dev that they return. You must eventually (possibly at module unload)
decrement the reference count on these devices by calling pci_dev_put().
3. Device Initialization Steps
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Device Initialization Steps
===========================
As noted in the introduction, most PCI drivers need the following steps
for device initialization:
Enable the device
Request MMIO/IOP resources
Set the DMA mask size (for both coherent and streaming DMA)
Allocate and initialize shared control data (pci_allocate_coherent())
Access device configuration space (if needed)
Register IRQ handler (request_irq())
Initialize non-PCI (i.e. LAN/SCSI/etc parts of the chip)
Enable DMA/processing engines.
- Enable the device
- Request MMIO/IOP resources
- Set the DMA mask size (for both coherent and streaming DMA)
- Allocate and initialize shared control data (pci_allocate_coherent())
- Access device configuration space (if needed)
- Register IRQ handler (request_irq())
- Initialize non-PCI (i.e. LAN/SCSI/etc parts of the chip)
- Enable DMA/processing engines.
The driver can access PCI config space registers at any time.
(Well, almost. When running BIST, config space can go away...but
@ -252,26 +193,29 @@ that will just result in a PCI Bus Master Abort and config reads
will return garbage).
3.1 Enable the PCI device
~~~~~~~~~~~~~~~~~~~~~~~~~
Enable the PCI device
---------------------
Before touching any device registers, the driver needs to enable
the PCI device by calling pci_enable_device(). This will:
o wake up the device if it was in suspended state,
o allocate I/O and memory regions of the device (if BIOS did not),
o allocate an IRQ (if BIOS did not).
NOTE: pci_enable_device() can fail! Check the return value.
- wake up the device if it was in suspended state,
- allocate I/O and memory regions of the device (if BIOS did not),
- allocate an IRQ (if BIOS did not).
[ OS BUG: we don't check resource allocations before enabling those
resources. The sequence would make more sense if we called
pci_request_resources() before calling pci_enable_device().
Currently, the device drivers can't detect the bug when when two
devices have been allocated the same range. This is not a common
problem and unlikely to get fixed soon.
.. note::
pci_enable_device() can fail! Check the return value.
.. warning::
OS BUG: we don't check resource allocations before enabling those
resources. The sequence would make more sense if we called
pci_request_resources() before calling pci_enable_device().
Currently, the device drivers can't detect the bug when when two
devices have been allocated the same range. This is not a common
problem and unlikely to get fixed soon.
This has been discussed before but not changed as of 2.6.19:
http://lkml.org/lkml/2006/3/2/194
This has been discussed before but not changed as of 2.6.19:
http://lkml.org/lkml/2006/3/2/194
]
pci_set_master() will enable DMA by setting the bus master bit
in the PCI_COMMAND register. It also fixes the latency timer value if
@ -288,8 +232,8 @@ pci_try_set_mwi() to have the system do its best effort at enabling
Mem-Wr-Inval.
3.2 Request MMIO/IOP resources
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Request MMIO/IOP resources
--------------------------
Memory (MMIO), and I/O port addresses should NOT be read directly
from the PCI device config space. Use the values in the pci_dev structure
as the PCI "bus address" might have been remapped to a "host physical"
@ -304,9 +248,10 @@ Conversely, drivers should call pci_release_region() AFTER
calling pci_disable_device().
The idea is to prevent two devices colliding on the same address range.
[ See OS BUG comment above. Currently (2.6.19), The driver can only
determine MMIO and IO Port resource availability _after_ calling
pci_enable_device(). ]
.. tip::
See OS BUG comment above. Currently (2.6.19), The driver can only
determine MMIO and IO Port resource availability _after_ calling
pci_enable_device().
Generic flavors of pci_request_region() are request_mem_region()
(for MMIO ranges) and request_region() (for IO Port ranges).
@ -316,12 +261,13 @@ BARs.
Also see pci_request_selected_regions() below.
3.3 Set the DMA mask size
~~~~~~~~~~~~~~~~~~~~~~~~~
[ If anything below doesn't make sense, please refer to
Documentation/DMA-API.txt. This section is just a reminder that
drivers need to indicate DMA capabilities of the device and is not
an authoritative source for DMA interfaces. ]
Set the DMA mask size
---------------------
.. note::
If anything below doesn't make sense, please refer to
Documentation/DMA-API.txt. This section is just a reminder that
drivers need to indicate DMA capabilities of the device and is not
an authoritative source for DMA interfaces.
While all drivers should explicitly indicate the DMA capability
(e.g. 32 or 64 bit) of the PCI bus master, devices with more than
@ -342,23 +288,23 @@ Many 64-bit "PCI" devices (before PCI-X) and some PCI-X devices are
("consistent") data.
3.4 Setup shared control data
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Setup shared control data
-------------------------
Once the DMA masks are set, the driver can allocate "consistent" (a.k.a. shared)
memory. See Documentation/DMA-API.txt for a full description of
the DMA APIs. This section is just a reminder that it needs to be done
before enabling DMA on the device.
3.5 Initialize device registers
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Initialize device registers
---------------------------
Some drivers will need specific "capability" fields programmed
or other "vendor specific" register initialized or reset.
E.g. clearing pending interrupts.
3.6 Register IRQ handler
~~~~~~~~~~~~~~~~~~~~~~~~
Register IRQ handler
--------------------
While calling request_irq() is the last step described here,
this is often just another intermediate step to initialize a device.
This step can often be deferred until the device is opened for use.
@ -396,6 +342,7 @@ and msix_enabled flags in the pci_dev structure after calling
pci_alloc_irq_vectors.
There are (at least) two really good reasons for using MSI:
1) MSI is an exclusive interrupt vector by definition.
This means the interrupt handler doesn't have to verify
its device caused the interrupt.
@ -410,24 +357,23 @@ See drivers/infiniband/hw/mthca/ or drivers/net/tg3.c for examples
of MSI/MSI-X usage.
4. PCI device shutdown
~~~~~~~~~~~~~~~~~~~~~~~
PCI device shutdown
===================
When a PCI device driver is being unloaded, most of the following
steps need to be performed:
Disable the device from generating IRQs
Release the IRQ (free_irq())
Stop all DMA activity
Release DMA buffers (both streaming and consistent)
Unregister from other subsystems (e.g. scsi or netdev)
Disable device from responding to MMIO/IO Port addresses
Release MMIO/IO Port resource(s)
- Disable the device from generating IRQs
- Release the IRQ (free_irq())
- Stop all DMA activity
- Release DMA buffers (both streaming and consistent)
- Unregister from other subsystems (e.g. scsi or netdev)
- Disable device from responding to MMIO/IO Port addresses
- Release MMIO/IO Port resource(s)
4.1 Stop IRQs on the device
~~~~~~~~~~~~~~~~~~~~~~~~~~~
Stop IRQs on the device
-----------------------
How to do this is chip/device specific. If it's not done, it opens
the possibility of a "screaming interrupt" if (and only if)
the IRQ is shared with another device.
@ -446,16 +392,16 @@ MSI and MSI-X are defined to be exclusive interrupts and thus
are not susceptible to the "screaming interrupt" problem.
4.2 Release the IRQ
~~~~~~~~~~~~~~~~~~~
Release the IRQ
---------------
Once the device is quiesced (no more IRQs), one can call free_irq().
This function will return control once any pending IRQs are handled,
"unhook" the drivers IRQ handler from that IRQ, and finally release
the IRQ if no one else is using it.
4.3 Stop all DMA activity
~~~~~~~~~~~~~~~~~~~~~~~~~
Stop all DMA activity
---------------------
It's extremely important to stop all DMA operations BEFORE attempting
to deallocate DMA control data. Failure to do so can result in memory
corruption, hangs, and on some chip-sets a hard crash.
@ -467,8 +413,8 @@ While this step sounds obvious and trivial, several "mature" drivers
didn't get this step right in the past.
4.4 Release DMA buffers
~~~~~~~~~~~~~~~~~~~~~~~
Release DMA buffers
-------------------
Once DMA is stopped, clean up streaming DMA first.
I.e. unmap data buffers and return buffers to "upstream"
owners if there is one.
@ -478,8 +424,8 @@ Then clean up "consistent" buffers which contain the control data.
See Documentation/DMA-API.txt for details on unmapping interfaces.
4.5 Unregister from other subsystems
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Unregister from other subsystems
--------------------------------
Most low level PCI device drivers support some other subsystem
like USB, ALSA, SCSI, NetDev, Infiniband, etc. Make sure your
driver isn't losing resources from that other subsystem.
@ -487,31 +433,30 @@ If this happens, typically the symptom is an Oops (panic) when
the subsystem attempts to call into a driver that has been unloaded.
4.6 Disable Device from responding to MMIO/IO Port addresses
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Disable Device from responding to MMIO/IO Port addresses
--------------------------------------------------------
io_unmap() MMIO or IO Port resources and then call pci_disable_device().
This is the symmetric opposite of pci_enable_device().
Do not access device registers after calling pci_disable_device().
4.7 Release MMIO/IO Port Resource(s)
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Release MMIO/IO Port Resource(s)
--------------------------------
Call pci_release_region() to mark the MMIO or IO Port range as available.
Failure to do so usually results in the inability to reload the driver.
How to access PCI config space
==============================
5. How to access PCI config space
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
You can use pci_(read|write)_config_(byte|word|dword) to access the config
space of a device represented by struct pci_dev *. All these functions return 0
when successful or an error code (PCIBIOS_...) which can be translated to a text
string by pcibios_strerror. Most drivers expect that accesses to valid PCI
You can use `pci_(read|write)_config_(byte|word|dword)` to access the config
space of a device represented by `struct pci_dev *`. All these functions return
0 when successful or an error code (`PCIBIOS_...`) which can be translated to a
text string by pcibios_strerror. Most drivers expect that accesses to valid PCI
devices don't fail.
If you don't have a struct pci_dev available, you can call
pci_bus_(read|write)_config_(byte|word|dword) to access a given device
`pci_bus_(read|write)_config_(byte|word|dword)` to access a given device
and function on that bus.
If you access fields in the standard portion of the config header, please
@ -522,10 +467,10 @@ pci_find_capability() for the particular capability and it will find the
corresponding register block for you.
Other interesting functions
===========================
6. Other interesting functions
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
============================= ================================================
pci_get_domain_bus_and_slot() Find pci_dev corresponding to given domain,
bus and slot and number. If the device is
found, its reference count is increased.
@ -539,11 +484,11 @@ pci_set_drvdata() Set private driver data pointer for a pci_dev
pci_get_drvdata() Return private driver data pointer for a pci_dev
pci_set_mwi() Enable Memory-Write-Invalidate transactions.
pci_clear_mwi() Disable Memory-Write-Invalidate transactions.
============================= ================================================
7. Miscellaneous hints
~~~~~~~~~~~~~~~~~~~~~~
Miscellaneous hints
===================
When displaying PCI device names to the user (for example when a driver wants
to tell the user what card has it found), please use pci_name(pci_dev).
@ -559,9 +504,8 @@ on the bus need to be capable of doing it, so this is something which needs
to be handled by platform and generic code, not individual drivers.
8. Vendor and device identifications
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Vendor and device identifications
=================================
Do not add new device or vendor IDs to include/linux/pci_ids.h unless they
are shared across multiple drivers. You can add private definitions in
@ -575,28 +519,27 @@ There are mirrors of the pci.ids file at http://pciids.sourceforge.net/
and https://github.com/pciutils/pciids.
9. Obsolete functions
~~~~~~~~~~~~~~~~~~~~~
Obsolete functions
==================
There are several functions which you might come across when trying to
port an old driver to the new PCI interface. They are no longer present
in the kernel as they aren't compatible with hotplug or PCI domains or
having sane locking.
================= ===========================================
pci_find_device() Superseded by pci_get_device()
pci_find_subsys() Superseded by pci_get_subsys()
pci_find_slot() Superseded by pci_get_domain_bus_and_slot()
pci_get_slot() Superseded by pci_get_domain_bus_and_slot()
================= ===========================================
The alternative is the traditional PCI device driver that walks PCI
device lists. This is still possible but discouraged.
10. MMIO Space and "Write Posting"
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
MMIO Space and "Write Posting"
==============================
Converting a driver from using I/O Port space to using MMIO space
often requires some additional changes. Specifically, "write posting"
@ -609,14 +552,14 @@ the CPU before the transaction has reached its destination.
Thus, timing sensitive code should add readl() where the CPU is
expected to wait before doing other work. The classic "bit banging"
sequence works fine for I/O Port space:
sequence works fine for I/O Port space::
for (i = 8; --i; val >>= 1) {
outb(val & 1, ioport_reg); /* write bit */
udelay(10);
}
The same sequence for MMIO space should be:
The same sequence for MMIO space should be::
for (i = 8; --i; val >>= 1) {
writeb(val & 1, mmio_reg); /* write bit */
@ -633,4 +576,3 @@ handle the PCI master abort on all platforms if the PCI device is
expected to not respond to a readl(). Most x86 platforms will allow
MMIO reads to master abort (a.k.a. "Soft Fail") and return garbage
(e.g. ~0). But many RISC platforms will crash (a.k.a."Hard Fail").

156
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@ -1,21 +1,29 @@
The PCI Express Advanced Error Reporting Driver Guide HOWTO
T. Long Nguyen <tom.l.nguyen@intel.com>
Yanmin Zhang <yanmin.zhang@intel.com>
07/29/2006
.. SPDX-License-Identifier: GPL-2.0
.. include:: <isonum.txt>
===========================================================
The PCI Express Advanced Error Reporting Driver Guide HOWTO
===========================================================
1. Overview
:Authors: - T. Long Nguyen <tom.l.nguyen@intel.com>
- Yanmin Zhang <yanmin.zhang@intel.com>
1.1 About this guide
:Copyright: |copy| 2006 Intel Corporation
Overview
===========
About this guide
----------------
This guide describes the basics of the PCI Express Advanced Error
Reporting (AER) driver and provides information on how to use it, as
well as how to enable the drivers of endpoint devices to conform with
PCI Express AER driver.
1.2 Copyright (C) Intel Corporation 2006.
1.3 What is the PCI Express AER Driver?
What is the PCI Express AER Driver?
-----------------------------------
PCI Express error signaling can occur on the PCI Express link itself
or on behalf of transactions initiated on the link. PCI Express
@ -30,17 +38,19 @@ The PCI Express AER driver provides the infrastructure to support PCI
Express Advanced Error Reporting capability. The PCI Express AER
driver provides three basic functions:
- Gathers the comprehensive error information if errors occurred.
- Reports error to the users.
- Performs error recovery actions.
- Gathers the comprehensive error information if errors occurred.
- Reports error to the users.
- Performs error recovery actions.
AER driver only attaches root ports which support PCI-Express AER
capability.
2. User Guide
User Guide
==========
2.1 Include the PCI Express AER Root Driver into the Linux Kernel
Include the PCI Express AER Root Driver into the Linux Kernel
-------------------------------------------------------------
The PCI Express AER Root driver is a Root Port service driver attached
to the PCI Express Port Bus driver. If a user wants to use it, the driver
@ -48,7 +58,8 @@ has to be compiled. Option CONFIG_PCIEAER supports this capability. It
depends on CONFIG_PCIEPORTBUS, so pls. set CONFIG_PCIEPORTBUS=y and
CONFIG_PCIEAER = y.
2.2 Load PCI Express AER Root Driver
Load PCI Express AER Root Driver
--------------------------------
Some systems have AER support in firmware. Enabling Linux AER support at
the same time the firmware handles AER may result in unpredictable
@ -56,30 +67,34 @@ behavior. Therefore, Linux does not handle AER events unless the firmware
grants AER control to the OS via the ACPI _OSC method. See the PCI FW 3.0
Specification for details regarding _OSC usage.
2.3 AER error output
AER error output
----------------
When a PCIe AER error is captured, an error message will be output to
console. If it's a correctable error, it is output as a warning.
Otherwise, it is printed as an error. So users could choose different
log level to filter out correctable error messages.
Below shows an example:
0000:50:00.0: PCIe Bus Error: severity=Uncorrected (Fatal), type=Transaction Layer, id=0500(Requester ID)
0000:50:00.0: device [8086:0329] error status/mask=00100000/00000000
0000:50:00.0: [20] Unsupported Request (First)
0000:50:00.0: TLP Header: 04000001 00200a03 05010000 00050100
Below shows an example::
0000:50:00.0: PCIe Bus Error: severity=Uncorrected (Fatal), type=Transaction Layer, id=0500(Requester ID)
0000:50:00.0: device [8086:0329] error status/mask=00100000/00000000
0000:50:00.0: [20] Unsupported Request (First)
0000:50:00.0: TLP Header: 04000001 00200a03 05010000 00050100
In the example, 'Requester ID' means the ID of the device who sends
the error message to root port. Pls. refer to pci express specs for
other fields.
2.4 AER Statistics / Counters
AER Statistics / Counters
-------------------------
When PCIe AER errors are captured, the counters / statistics are also exposed
in the form of sysfs attributes which are documented at
Documentation/ABI/testing/sysfs-bus-pci-devices-aer_stats
3. Developer Guide
Developer Guide
===============
To enable AER aware support requires a software driver to configure
the AER capability structure within its device and to provide callbacks.
@ -120,7 +135,8 @@ hierarchy and links. These errors do not include any device specific
errors because device specific errors will still get sent directly to
the device driver.
3.1 Configure the AER capability structure
Configure the AER capability structure
--------------------------------------
AER aware drivers of PCI Express component need change the device
control registers to enable AER. They also could change AER registers,
@ -128,9 +144,11 @@ including mask and severity registers. Helper function
pci_enable_pcie_error_reporting could be used to enable AER. See
section 3.3.
3.2. Provide callbacks
Provide callbacks
-----------------
3.2.1 callback reset_link to reset pci express link
callback reset_link to reset pci express link
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
This callback is used to reset the pci express physical link when a
fatal error happens. The root port aer service driver provides a
@ -140,13 +158,15 @@ upstream ports should provide their own reset_link functions.
In struct pcie_port_service_driver, a new pointer, reset_link, is
added.
::
pci_ers_result_t (*reset_link) (struct pci_dev *dev);
pci_ers_result_t (*reset_link) (struct pci_dev *dev);
Section 3.2.2.2 provides more detailed info on when to call
reset_link.
3.2.2 PCI error-recovery callbacks
PCI error-recovery callbacks
~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The PCI Express AER Root driver uses error callbacks to coordinate
with downstream device drivers associated with a hierarchy in question
@ -161,7 +181,8 @@ definitions of the callbacks.
Below sections specify when to call the error callback functions.
3.2.2.1 Correctable errors
Correctable errors
~~~~~~~~~~~~~~~~~~
Correctable errors pose no impacts on the functionality of
the interface. The PCI Express protocol can recover without any
@ -169,13 +190,16 @@ software intervention or any loss of data. These errors do not
require any recovery actions. The AER driver clears the device's
correctable error status register accordingly and logs these errors.
3.2.2.2 Non-correctable (non-fatal and fatal) errors
Non-correctable (non-fatal and fatal) errors
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
If an error message indicates a non-fatal error, performing link reset
at upstream is not required. The AER driver calls error_detected(dev,
pci_channel_io_normal) to all drivers associated within a hierarchy in
question. for example,
EndPoint<==>DownstreamPort B<==>UpstreamPort A<==>RootPort.
question. for example::
EndPoint<==>DownstreamPort B<==>UpstreamPort A<==>RootPort
If Upstream port A captures an AER error, the hierarchy consists of
Downstream port B and EndPoint.
@ -199,53 +223,72 @@ function. If error_detected returns PCI_ERS_RESULT_CAN_RECOVER and
reset_link returns PCI_ERS_RESULT_RECOVERED, the error handling goes
to mmio_enabled.
3.3 helper functions
helper functions
----------------
::
int pci_enable_pcie_error_reporting(struct pci_dev *dev);
3.3.1 int pci_enable_pcie_error_reporting(struct pci_dev *dev);
pci_enable_pcie_error_reporting enables the device to send error
messages to root port when an error is detected. Note that devices
don't enable the error reporting by default, so device drivers need
call this function to enable it.
3.3.2 int pci_disable_pcie_error_reporting(struct pci_dev *dev);
::
int pci_disable_pcie_error_reporting(struct pci_dev *dev);
pci_disable_pcie_error_reporting disables the device to send error
messages to root port when an error is detected.
3.3.3 int pci_cleanup_aer_uncorrect_error_status(struct pci_dev *dev);
::
int pci_cleanup_aer_uncorrect_error_status(struct pci_dev *dev);`
pci_cleanup_aer_uncorrect_error_status cleanups the uncorrectable
error status register.
3.4 Frequent Asked Questions
Frequent Asked Questions
------------------------
Q: What happens if a PCI Express device driver does not provide an
error recovery handler (pci_driver->err_handler is equal to NULL)?
Q:
What happens if a PCI Express device driver does not provide an
error recovery handler (pci_driver->err_handler is equal to NULL)?
A: The devices attached with the driver won't be recovered. If the
error is fatal, kernel will print out warning messages. Please refer
to section 3 for more information.
A:
The devices attached with the driver won't be recovered. If the
error is fatal, kernel will print out warning messages. Please refer
to section 3 for more information.
Q: What happens if an upstream port service driver does not provide
callback reset_link?
Q:
What happens if an upstream port service driver does not provide
callback reset_link?
A: Fatal error recovery will fail if the errors are reported by the
upstream ports who are attached by the service driver.
A:
Fatal error recovery will fail if the errors are reported by the
upstream ports who are attached by the service driver.
Q: How does this infrastructure deal with driver that is not PCI
Express aware?
Q:
How does this infrastructure deal with driver that is not PCI
Express aware?
A: This infrastructure calls the error callback functions of the
driver when an error happens. But if the driver is not aware of
PCI Express, the device might not report its own errors to root
port.
A:
This infrastructure calls the error callback functions of the
driver when an error happens. But if the driver is not aware of
PCI Express, the device might not report its own errors to root
port.
Q: What modifications will that driver need to make it compatible
with the PCI Express AER Root driver?
Q:
What modifications will that driver need to make it compatible
with the PCI Express AER Root driver?
A: It could call the helper functions to enable AER in devices and
cleanup uncorrectable status register. Pls. refer to section 3.3.
A:
It could call the helper functions to enable AER in devices and
cleanup uncorrectable status register. Pls. refer to section 3.3.
4. Software error injection
Software error injection
========================
Debugging PCIe AER error recovery code is quite difficult because it
is hard to trigger real hardware errors. Software based error
@ -261,6 +304,7 @@ After reboot with new kernel or insert the module, a device file named
Then, you need a user space tool named aer-inject, which can be gotten
from:
https://git.kernel.org/cgit/linux/kernel/git/gong.chen/aer-inject.git/
More information about aer-inject can be found in the document comes

140
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@ -1,16 +1,23 @@
The PCI Express Port Bus Driver Guide HOWTO
Tom L Nguyen tom.l.nguyen@intel.com
11/03/2004
.. SPDX-License-Identifier: GPL-2.0
.. include:: <isonum.txt>
1. About this guide
===========================================
The PCI Express Port Bus Driver Guide HOWTO
===========================================
:Author: Tom L Nguyen tom.l.nguyen@intel.com 11/03/2004
:Copyright: |copy| 2004 Intel Corporation
About this guide
================
This guide describes the basics of the PCI Express Port Bus driver
and provides information on how to enable the service drivers to
register/unregister with the PCI Express Port Bus Driver.
2. Copyright 2004 Intel Corporation
3. What is the PCI Express Port Bus Driver
What is the PCI Express Port Bus Driver
=======================================
A PCI Express Port is a logical PCI-PCI Bridge structure. There
are two types of PCI Express Port: the Root Port and the Switch
@ -30,7 +37,8 @@ support (AER), and virtual channel support (VC). These services may
be handled by a single complex driver or be individually distributed
and handled by corresponding service drivers.
4. Why use the PCI Express Port Bus Driver?
Why use the PCI Express Port Bus Driver?
========================================
In existing Linux kernels, the Linux Device Driver Model allows a
physical device to be handled by only a single driver. The PCI
@ -51,28 +59,31 @@ PCI Express Ports and distributes all provided service requests
to the corresponding service drivers as required. Some key
advantages of using the PCI Express Port Bus driver are listed below:
- Allow multiple service drivers to run simultaneously on
a PCI-PCI Bridge Port device.
- Allow multiple service drivers to run simultaneously on
a PCI-PCI Bridge Port device.
- Allow service drivers implemented in an independent
staged approach.
- Allow service drivers implemented in an independent
staged approach.
- Allow one service driver to run on multiple PCI-PCI Bridge
Port devices.
- Allow one service driver to run on multiple PCI-PCI Bridge
Port devices.
- Manage and distribute resources of a PCI-PCI Bridge Port
device to requested service drivers.
- Manage and distribute resources of a PCI-PCI Bridge Port
device to requested service drivers.
5. Configuring the PCI Express Port Bus Driver vs. Service Drivers
Configuring the PCI Express Port Bus Driver vs. Service Drivers
===============================================================
5.1 Including the PCI Express Port Bus Driver Support into the Kernel
Including the PCI Express Port Bus Driver Support into the Kernel
-----------------------------------------------------------------
Including the PCI Express Port Bus driver depends on whether the PCI
Express support is included in the kernel config. The kernel will
automatically include the PCI Express Port Bus driver as a kernel
driver when the PCI Express support is enabled in the kernel.
5.2 Enabling Service Driver Support
Enabling Service Driver Support
-------------------------------
PCI device drivers are implemented based on Linux Device Driver Model.
All service drivers are PCI device drivers. As discussed above, it is
@ -89,9 +100,11 @@ header file /include/linux/pcieport_if.h, before calling these APIs.
Failure to do so will result an identity mismatch, which prevents
the PCI Express Port Bus driver from loading a service driver.
5.2.1 pcie_port_service_register
pcie_port_service_register
~~~~~~~~~~~~~~~~~~~~~~~~~~
::
int pcie_port_service_register(struct pcie_port_service_driver *new)
int pcie_port_service_register(struct pcie_port_service_driver *new)
This API replaces the Linux Driver Model's pci_register_driver API. A
service driver should always calls pcie_port_service_register at
@ -99,69 +112,76 @@ module init. Note that after service driver being loaded, calls
such as pci_enable_device(dev) and pci_set_master(dev) are no longer
necessary since these calls are executed by the PCI Port Bus driver.
5.2.2 pcie_port_service_unregister
pcie_port_service_unregister
~~~~~~~~~~~~~~~~~~~~~~~~~~~~
::
void pcie_port_service_unregister(struct pcie_port_service_driver *new)
void pcie_port_service_unregister(struct pcie_port_service_driver *new)
pcie_port_service_unregister replaces the Linux Driver Model's
pci_unregister_driver. It's always called by service driver when a
module exits.
5.2.3 Sample Code
Sample Code
~~~~~~~~~~~
Below is sample service driver code to initialize the port service
driver data structure.
::
static struct pcie_port_service_id service_id[] = { {
.vendor = PCI_ANY_ID,
.device = PCI_ANY_ID,
.port_type = PCIE_RC_PORT,
.service_type = PCIE_PORT_SERVICE_AER,
}, { /* end: all zeroes */ }
};
static struct pcie_port_service_id service_id[] = { {
.vendor = PCI_ANY_ID,
.device = PCI_ANY_ID,
.port_type = PCIE_RC_PORT,
.service_type = PCIE_PORT_SERVICE_AER,
}, { /* end: all zeroes */ }
};
static struct pcie_port_service_driver root_aerdrv = {
.name = (char *)device_name,
.id_table = &service_id[0],
static struct pcie_port_service_driver root_aerdrv = {
.name = (char *)device_name,
.id_table = &service_id[0],
.probe = aerdrv_load,
.remove = aerdrv_unload,
.probe = aerdrv_load,
.remove = aerdrv_unload,
.suspend = aerdrv_suspend,
.resume = aerdrv_resume,
};
.suspend = aerdrv_suspend,
.resume = aerdrv_resume,
};
Below is a sample code for registering/unregistering a service
driver.
::
static int __init aerdrv_service_init(void)
{
int retval = 0;
static int __init aerdrv_service_init(void)
{
int retval = 0;
retval = pcie_port_service_register(&root_aerdrv);
if (!retval) {
/*
* FIX ME
*/
}
return retval;
}
retval = pcie_port_service_register(&root_aerdrv);
if (!retval) {
/*
* FIX ME
*/
}
return retval;
}
static void __exit aerdrv_service_exit(void)
{
pcie_port_service_unregister(&root_aerdrv);
}
static void __exit aerdrv_service_exit(void)
{
pcie_port_service_unregister(&root_aerdrv);
}
module_init(aerdrv_service_init);
module_exit(aerdrv_service_exit);
module_init(aerdrv_service_init);
module_exit(aerdrv_service_exit);
6. Possible Resource Conflicts
Possible Resource Conflicts
===========================
Since all service drivers of a PCI-PCI Bridge Port device are
allowed to run simultaneously, below lists a few of possible resource
conflicts with proposed solutions.
6.1 MSI and MSI-X Vector Resource
MSI and MSI-X Vector Resource
-----------------------------
Once MSI or MSI-X interrupts are enabled on a device, it stays in this
mode until they are disabled again. Since service drivers of the same
@ -179,7 +199,8 @@ driver. Service drivers should use (struct pcie_device*)dev->irq to
call request_irq/free_irq. In addition, the interrupt mode is stored
in the field interrupt_mode of struct pcie_device.
6.3 PCI Memory/IO Mapped Regions
PCI Memory/IO Mapped Regions
----------------------------
Service drivers for PCI Express Power Management (PME), Advanced
Error Reporting (AER), Hot-Plug (HP) and Virtual Channel (VC) access
@ -188,7 +209,8 @@ registers accessed are independent of each other. This patch assumes
that all service drivers will be well behaved and not overwrite
other service driver's configuration settings.
6.4 PCI Config Registers
PCI Config Registers
--------------------
Each service driver runs its PCI config operations on its own
capability structure except the PCI Express capability structure, in

14
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@ -1,3 +1,7 @@
==================
Control Groupstats
==================
Control Groupstats is inspired by the discussion at
http://lkml.org/lkml/2007/4/11/187 and implements per cgroup statistics as
suggested by Andrew Morton in http://lkml.org/lkml/2007/4/11/263.
@ -19,9 +23,9 @@ about tasks blocked on I/O. If CONFIG_TASK_DELAY_ACCT is disabled, this
information will not be available.
To extract cgroup statistics a utility very similar to getdelays.c
has been developed, the sample output of the utility is shown below
has been developed, the sample output of the utility is shown below::
~/balbir/cgroupstats # ./getdelays -C "/sys/fs/cgroup/a"
sleeping 1, blocked 0, running 1, stopped 0, uninterruptible 0
~/balbir/cgroupstats # ./getdelays -C "/sys/fs/cgroup"
sleeping 155, blocked 0, running 1, stopped 0, uninterruptible 2
~/balbir/cgroupstats # ./getdelays -C "/sys/fs/cgroup/a"
sleeping 1, blocked 0, running 1, stopped 0, uninterruptible 0
~/balbir/cgroupstats # ./getdelays -C "/sys/fs/cgroup"
sleeping 155, blocked 0, running 1, stopped 0, uninterruptible 2

61
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View File

@ -1,5 +1,6 @@
================
Delay accounting
----------------
================
Tasks encounter delays in execution when they wait
for some kernel resource to become available e.g. a
@ -39,7 +40,9 @@ in detail in a separate document in this directory. Taskstats returns a
generic data structure to userspace corresponding to per-pid and per-tgid
statistics. The delay accounting functionality populates specific fields of
this structure. See
include/linux/taskstats.h
for a description of the fields pertaining to delay accounting.
It will generally be in the form of counters returning the cumulative
delay seen for cpu, sync block I/O, swapin, memory reclaim etc.
@ -61,13 +64,16 @@ also serves as an example of using the taskstats interface.
Usage
-----
Compile the kernel with
Compile the kernel with::
CONFIG_TASK_DELAY_ACCT=y
CONFIG_TASKSTATS=y
Delay accounting is enabled by default at boot up.
To disable, add
To disable, add::
nodelayacct
to the kernel boot options. The rest of the instructions
below assume this has not been done.
@ -78,40 +84,43 @@ The utility also allows a given command to be
executed and the corresponding delays to be
seen.
General format of the getdelays command
General format of the getdelays command::
getdelays [-t tgid] [-p pid] [-c cmd...]
getdelays [-t tgid] [-p pid] [-c cmd...]
Get delays, since system boot, for pid 10
# ./getdelays -p 10
(output similar to next case)
Get delays, since system boot, for pid 10::
Get sum of delays, since system boot, for all pids with tgid 5
# ./getdelays -t 5
# ./getdelays -p 10
(output similar to next case)
Get sum of delays, since system boot, for all pids with tgid 5::
# ./getdelays -t 5
CPU count real total virtual total delay total
7876 92005750 100000000 24001500
IO count delay total
0 0
SWAP count delay total
0 0
RECLAIM count delay total
0 0
CPU count real total virtual total delay total
7876 92005750 100000000 24001500
IO count delay total
0 0
SWAP count delay total
0 0
RECLAIM count delay total
0 0
Get delays seen in executing a given simple command
# ./getdelays -c ls /
Get delays seen in executing a given simple command::
bin data1 data3 data5 dev home media opt root srv sys usr
boot data2 data4 data6 etc lib mnt proc sbin subdomain tmp var
# ./getdelays -c ls /
bin data1 data3 data5 dev home media opt root srv sys usr
boot data2 data4 data6 etc lib mnt proc sbin subdomain tmp var
CPU count real total virtual total delay total
CPU count real total virtual total delay total
6 4000250 4000000 0
IO count delay total
IO count delay total
0 0
SWAP count delay total
SWAP count delay total
0 0
RECLAIM count delay total
RECLAIM count delay total
0 0

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@ -0,0 +1,14 @@
.. SPDX-License-Identifier: GPL-2.0
==========
Accounting
==========
.. toctree::
:maxdepth: 1
cgroupstats
delay-accounting
psi
taskstats
taskstats-struct

40
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@ -35,14 +35,14 @@ Pressure interface
Pressure information for each resource is exported through the
respective file in /proc/pressure/ -- cpu, memory, and io.
The format for CPU is as such:
The format for CPU is as such::
some avg10=0.00 avg60=0.00 avg300=0.00 total=0
some avg10=0.00 avg60=0.00 avg300=0.00 total=0
and for memory and IO:
and for memory and IO::
some avg10=0.00 avg60=0.00 avg300=0.00 total=0
full avg10=0.00 avg60=0.00 avg300=0.00 total=0
some avg10=0.00 avg60=0.00 avg300=0.00 total=0
full avg10=0.00 avg60=0.00 avg300=0.00 total=0
The "some" line indicates the share of time in which at least some
tasks are stalled on a given resource.
@ -77,9 +77,9 @@ To register a trigger user has to open psi interface file under
/proc/pressure/ representing the resource to be monitored and write the
desired threshold and time window. The open file descriptor should be
used to wait for trigger events using select(), poll() or epoll().
The following format is used:
The following format is used::
<some|full> <stall amount in us> <time window in us>
<some|full> <stall amount in us> <time window in us>
For example writing "some 150000 1000000" into /proc/pressure/memory
would add 150ms threshold for partial memory stall measured within
@ -115,18 +115,20 @@ trigger is closed.
Userspace monitor usage example
===============================
#include <errno.h>
#include <fcntl.h>
#include <stdio.h>
#include <poll.h>
#include <string.h>
#include <unistd.h>
::
/*
* Monitor memory partial stall with 1s tracking window size
* and 150ms threshold.
*/
int main() {
#include <errno.h>
#include <fcntl.h>
#include <stdio.h>
#include <poll.h>
#include <string.h>
#include <unistd.h>
/*
* Monitor memory partial stall with 1s tracking window size
* and 150ms threshold.
*/
int main() {
const char trig[] = "some 150000 1000000";
struct pollfd fds;
int n;
@ -165,7 +167,7 @@ int main() {
}
return 0;
}
}
Cgroup2 interface
=================

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@ -1,5 +1,6 @@
====================
The struct taskstats
--------------------
====================
This document contains an explanation of the struct taskstats fields.
@ -10,16 +11,24 @@ There are three different groups of fields in the struct taskstats:
the common fields and basic accounting fields are collected for
delivery at do_exit() of a task.
2) Delay accounting fields
These fields are placed between
/* Delay accounting fields start */
and
/* Delay accounting fields end */
These fields are placed between::
/* Delay accounting fields start */
and::
/* Delay accounting fields end */
Their values are collected if CONFIG_TASK_DELAY_ACCT is set.
3) Extended accounting fields
These fields are placed between
/* Extended accounting fields start */
and
/* Extended accounting fields end */
These fields are placed between::
/* Extended accounting fields start */
and::
/* Extended accounting fields end */
Their values are collected if CONFIG_TASK_XACCT is set.
4) Per-task and per-thread context switch count statistics
@ -31,31 +40,33 @@ There are three different groups of fields in the struct taskstats:
Future extension should add fields to the end of the taskstats struct, and
should not change the relative position of each field within the struct.
::
struct taskstats {
struct taskstats {
1) Common and basic accounting fields::
1) Common and basic accounting fields:
/* The version number of this struct. This field is always set to
* TAKSTATS_VERSION, which is defined in <linux/taskstats.h>.
* Each time the struct is changed, the value should be incremented.
*/
__u16 version;
/* The exit code of a task. */
/* The exit code of a task. */
__u32 ac_exitcode; /* Exit status */
/* The accounting flags of a task as defined in <linux/acct.h>
/* The accounting flags of a task as defined in <linux/acct.h>
* Defined values are AFORK, ASU, ACOMPAT, ACORE, and AXSIG.
*/
__u8 ac_flag; /* Record flags */
/* The value of task_nice() of a task. */
/* The value of task_nice() of a task. */
__u8 ac_nice; /* task_nice */
/* The name of the command that started this task. */
/* The name of the command that started this task. */
char ac_comm[TS_COMM_LEN]; /* Command name */
/* The scheduling discipline as set in task->policy field. */
/* The scheduling discipline as set in task->policy field. */
__u8 ac_sched; /* Scheduling discipline */
__u8 ac_pad[3];
@ -64,26 +75,27 @@ struct taskstats {
__u32 ac_pid; /* Process ID */
__u32 ac_ppid; /* Parent process ID */
/* The time when a task begins, in [secs] since 1970. */
/* The time when a task begins, in [secs] since 1970. */
__u32 ac_btime; /* Begin time [sec since 1970] */
/* The elapsed time of a task, in [usec]. */
/* The elapsed time of a task, in [usec]. */
__u64 ac_etime; /* Elapsed time [usec] */
/* The user CPU time of a task, in [usec]. */
/* The user CPU time of a task, in [usec]. */
__u64 ac_utime; /* User CPU time [usec] */
/* The system CPU time of a task, in [usec]. */
/* The system CPU time of a task, in [usec]. */
__u64 ac_stime; /* System CPU time [usec] */
/* The minor page fault count of a task, as set in task->min_flt. */
/* The minor page fault count of a task, as set in task->min_flt. */
__u64 ac_minflt; /* Minor Page Fault Count */
/* The major page fault count of a task, as set in task->maj_flt. */
__u64 ac_majflt; /* Major Page Fault Count */
2) Delay accounting fields:
2) Delay accounting fields::
/* Delay accounting fields start
*
* All values, until the comment "Delay accounting fields end" are
@ -134,7 +146,8 @@ struct taskstats {
/* version 1 ends here */
3) Extended accounting fields
3) Extended accounting fields::
/* Extended accounting fields start */
/* Accumulated RSS usage in duration of a task, in MBytes-usecs.
@ -145,15 +158,15 @@ struct taskstats {
*/
__u64 coremem; /* accumulated RSS usage in MB-usec */
/* Accumulated virtual memory usage in duration of a task.
/* Accumulated virtual memory usage in duration of a task.
* Same as acct_rss_mem1 above except that we keep track of VM usage.
*/
__u64 virtmem; /* accumulated VM usage in MB-usec */
/* High watermark of RSS usage in duration of a task, in KBytes. */
/* High watermark of RSS usage in duration of a task, in KBytes. */
__u64 hiwater_rss; /* High-watermark of RSS usage */
/* High watermark of VM usage in duration of a task, in KBytes. */
/* High watermark of VM usage in duration of a task, in KBytes. */
__u64 hiwater_vm; /* High-water virtual memory usage */
/* The following four fields are I/O statistics of a task. */
@ -164,17 +177,23 @@ struct taskstats {
/* Extended accounting fields end */
4) Per-task and per-thread statistics
4) Per-task and per-thread statistics::
__u64 nvcsw; /* Context voluntary switch counter */
__u64 nivcsw; /* Context involuntary switch counter */
5) Time accounting for SMT machines
5) Time accounting for SMT machines::
__u64 ac_utimescaled; /* utime scaled on frequency etc */
__u64 ac_stimescaled; /* stime scaled on frequency etc */
__u64 cpu_scaled_run_real_total; /* scaled cpu_run_real_total */
6) Extended delay accounting fields for memory reclaim
6) Extended delay accounting fields for memory reclaim::
/* Delay waiting for memory reclaim */
__u64 freepages_count;
__u64 freepages_delay_total;
}
::
}

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@ -1,5 +1,6 @@
=============================
Per-task statistics interface
-----------------------------
=============================
Taskstats is a netlink-based interface for sending per-task and
@ -65,7 +66,7 @@ taskstats.h file.
The data exchanged between user and kernel space is a netlink message belonging
to the NETLINK_GENERIC family and using the netlink attributes interface.
The messages are in the format
The messages are in the format::
+----------+- - -+-------------+-------------------+
| nlmsghdr | Pad | genlmsghdr | taskstats payload |
@ -167,15 +168,13 @@ extended and the number of cpus grows large.
To avoid losing statistics, userspace should do one or more of the following:
- increase the receive buffer sizes for the netlink sockets opened by
listeners to receive exit data.
listeners to receive exit data.
- create more listeners and reduce the number of cpus being listened to by
each listener. In the extreme case, there could be one listener for each cpu.
Users may also consider setting the cpu affinity of the listener to the subset
of cpus to which it listens, especially if they are listening to just one cpu.
each listener. In the extreme case, there could be one listener for each cpu.
Users may also consider setting the cpu affinity of the listener to the subset
of cpus to which it listens, especially if they are listening to just one cpu.
Despite these measures, if the userspace receives ENOBUFS error messages
indicated overflow of receive buffers, it should take measures to handle the
loss of data.
----

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@ -20,7 +20,7 @@ driver. The aoetools are on sourceforge.
http://aoetools.sourceforge.net/
The scripts in this Documentation/aoe directory are intended to
The scripts in this Documentation/admin-guide/aoe directory are intended to
document the use of the driver and are not necessary if you install
the aoetools.
@ -86,7 +86,7 @@ Using sysfs
a convenient way. Users with aoetools should use the aoe-stat
command::
root@makki root# sh Documentation/aoe/status.sh
root@makki root# sh Documentation/admin-guide/aoe/status.sh
e10.0 eth3 up
e10.1 eth3 up
e10.2 eth3 up

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2
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@ -1,5 +1,3 @@
:orphan:
=======================
ATA over Ethernet (AoE)
=======================

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2
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@ -11,7 +11,7 @@
# udev_rules="/etc/udev/rules.d/"
# bash# ls /etc/udev/rules.d/
# 10-wacom.rules 50-udev.rules
# bash# cp /path/to/linux/Documentation/aoe/udev.txt \
# bash# cp /path/to/linux/Documentation/admin-guide/aoe/udev.txt \
# /etc/udev/rules.d/60-aoe.rules
#

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@ -1,3 +1,7 @@
================================
kernel data structure for DRBD-9
================================
This describes the in kernel data structure for DRBD-9. Starting with
Linux v3.14 we are reorganizing DRBD to use this data structure.
@ -10,7 +14,7 @@ device is represented by a block device locally.
The DRBD objects are interconnected to form a matrix as depicted below; a
drbd_peer_device object sits at each intersection between a drbd_device and a
drbd_connection:
drbd_connection::
/--------------+---------------+.....+---------------\
| resource | device | | device |

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@ -0,0 +1,30 @@
.. SPDX-License-Identifier: GPL-2.0
.. The here included files are intended to help understand the implementation
Data flows that Relate some functions, and write packets
========================================================
.. kernel-figure:: DRBD-8.3-data-packets.svg
:alt: DRBD-8.3-data-packets.svg
:align: center
.. kernel-figure:: DRBD-data-packets.svg
:alt: DRBD-data-packets.svg
:align: center
Sub graphs of DRBD's state transitions
======================================
.. kernel-figure:: conn-states-8.dot
:alt: conn-states-8.dot
:align: center
.. kernel-figure:: disk-states-8.dot
:alt: disk-states-8.dot
:align: center
.. kernel-figure:: node-states-8.dot
:alt: node-states-8.dot
:align: center

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@ -1,4 +1,9 @@
==========================================
Distributed Replicated Block Device - DRBD
==========================================
Description
===========
DRBD is a shared-nothing, synchronously replicated block device. It
is designed to serve as a building block for high availability
@ -7,10 +12,8 @@ Description
Please visit http://www.drbd.org to find out more.
The here included files are intended to help understand the implementation
.. toctree::
:maxdepth: 1
DRBD-8.3-data-packets.svg, DRBD-data-packets.svg
relates some functions, and write packets.
conn-states-8.dot, disk-states-8.dot, node-states-8.dot
The sub graphs of DRBD's state transitions
data-structure-v9
figures

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@ -11,4 +11,3 @@ digraph peer_states {
Unknown -> Primary [ label = "connected" ]
Unknown -> Secondary [ label = "connected" ]
}

88
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@ -1,35 +1,37 @@
This file describes the floppy driver.
=============
Floppy Driver
=============
FAQ list:
=========
A FAQ list may be found in the fdutils package (see below), and also
A FAQ list may be found in the fdutils package (see below), and also
at <http://fdutils.linux.lu/faq.html>.
LILO configuration options (Thinkpad users, read this)
======================================================
The floppy driver is configured using the 'floppy=' option in
The floppy driver is configured using the 'floppy=' option in
lilo. This option can be typed at the boot prompt, or entered in the
lilo configuration file.
Example: If your kernel is called linux-2.6.9, type the following line
at the lilo boot prompt (if you have a thinkpad):
Example: If your kernel is called linux-2.6.9, type the following line
at the lilo boot prompt (if you have a thinkpad)::
linux-2.6.9 floppy=thinkpad
You may also enter the following line in /etc/lilo.conf, in the description
of linux-2.6.9:
of linux-2.6.9::
append = "floppy=thinkpad"
Several floppy related options may be given, example:
Several floppy related options may be given, example::
linux-2.6.9 floppy=daring floppy=two_fdc
append = "floppy=daring floppy=two_fdc"
If you give options both in the lilo config file and on the boot
If you give options both in the lilo config file and on the boot
prompt, the option strings of both places are concatenated, the boot
prompt options coming last. That's why there are also options to
restore the default behavior.
@ -38,21 +40,23 @@ restore the default behavior.
Module configuration options
============================
If you use the floppy driver as a module, use the following syntax:
modprobe floppy floppy="<options>"
If you use the floppy driver as a module, use the following syntax::
Example:
modprobe floppy floppy="omnibook messages"
modprobe floppy floppy="<options>"
If you need certain options enabled every time you load the floppy driver,
you can put:
Example::
options floppy floppy="omnibook messages"
modprobe floppy floppy="omnibook messages"
If you need certain options enabled every time you load the floppy driver,
you can put::
options floppy floppy="omnibook messages"
in a configuration file in /etc/modprobe.d/.
The floppy driver related options are:
The floppy driver related options are:
floppy=asus_pci
Sets the bit mask to allow only units 0 and 1. (default)
@ -70,8 +74,7 @@ in a configuration file in /etc/modprobe.d/.
Tells the floppy driver that you have only one floppy controller.
(default)
floppy=two_fdc
floppy=<address>,two_fdc
floppy=two_fdc / floppy=<address>,two_fdc
Tells the floppy driver that you have two floppy controllers.
The second floppy controller is assumed to be at <address>.
This option is not needed if the second controller is at address
@ -84,8 +87,7 @@ in a configuration file in /etc/modprobe.d/.
floppy=0,thinkpad
Tells the floppy driver that you don't have a Thinkpad.
floppy=omnibook
floppy=nodma
floppy=omnibook / floppy=nodma
Tells the floppy driver not to use Dma for data transfers.
This is needed on HP Omnibooks, which don't have a workable
DMA channel for the floppy driver. This option is also useful
@ -144,14 +146,16 @@ in a configuration file in /etc/modprobe.d/.
described in the physical CMOS), or if your BIOS uses
non-standard CMOS types. The CMOS types are:
0 - Use the value of the physical CMOS
1 - 5 1/4 DD
2 - 5 1/4 HD
3 - 3 1/2 DD
4 - 3 1/2 HD
5 - 3 1/2 ED
6 - 3 1/2 ED
16 - unknown or not installed
== ==================================
0 Use the value of the physical CMOS
1 5 1/4 DD
2 5 1/4 HD
3 3 1/2 DD
4 3 1/2 HD
5 3 1/2 ED
6 3 1/2 ED
16 unknown or not installed
== ==================================
(Note: there are two valid types for ED drives. This is because 5 was
initially chosen to represent floppy *tapes*, and 6 for ED drives.
@ -162,8 +166,7 @@ in a configuration file in /etc/modprobe.d/.
Print a warning message when an unexpected interrupt is received.
(default)
floppy=no_unexpected_interrupts
floppy=L40SX
floppy=no_unexpected_interrupts / floppy=L40SX
Don't print a message when an unexpected interrupt is received. This
is needed on IBM L40SX laptops in certain video modes. (There seems
to be an interaction between video and floppy. The unexpected
@ -199,47 +202,54 @@ in a configuration file in /etc/modprobe.d/.
Sets the floppy DMA channel to <nr> instead of 2.
floppy=slow
Use PS/2 stepping rate:
" PS/2 floppies have much slower step rates than regular floppies.
Use PS/2 stepping rate::
PS/2 floppies have much slower step rates than regular floppies.
It's been recommended that take about 1/4 of the default speed
in some more extreme cases."
in some more extreme cases.
Supporting utilities and additional documentation:
==================================================
Additional parameters of the floppy driver can be configured at
Additional parameters of the floppy driver can be configured at
runtime. Utilities which do this can be found in the fdutils package.
This package also contains a new version of mtools which allows to
access high capacity disks (up to 1992K on a high density 3 1/2 disk!).
It also contains additional documentation about the floppy driver.
The latest version can be found at fdutils homepage:
http://fdutils.linux.lu
The fdutils releases can be found at:
http://fdutils.linux.lu/download.html
http://www.tux.org/pub/knaff/fdutils/
ftp://metalab.unc.edu/pub/Linux/utils/disk-management/
Reporting problems about the floppy driver
==========================================
If you have a question or a bug report about the floppy driver, mail
If you have a question or a bug report about the floppy driver, mail
me at Alain.Knaff@poboxes.com . If you post to Usenet, preferably use
comp.os.linux.hardware. As the volume in these groups is rather high,
be sure to include the word "floppy" (or "FLOPPY") in the subject
line. If the reported problem happens when mounting floppy disks, be
sure to mention also the type of the filesystem in the subject line.
Be sure to read the FAQ before mailing/posting any bug reports!
Be sure to read the FAQ before mailing/posting any bug reports!
Alain
Alain
Changelog
=========
10-30-2004 : Cleanup, updating, add reference to module configuration.
10-30-2004 :
Cleanup, updating, add reference to module configuration.
James Nelson <james4765@gmail.com>
6-3-2000 : Original Document
6-3-2000 :
Original Document

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@ -0,0 +1,16 @@
.. SPDX-License-Identifier: GPL-2.0
===========================
The Linux RapidIO Subsystem
===========================
.. toctree::
:maxdepth: 1
floppy
nbd
paride
ramdisk
zram
drbd/index

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@ -1,3 +1,4 @@
==================================
Network Block Device (TCP version)
==================================
@ -28,4 +29,3 @@ max_part
nbds_max
Number of block devices that should be initialized (default: 16).

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@ -1,15 +1,17 @@
Linux and parallel port IDE devices
===================================
Linux and parallel port IDE devices
===================================
PARIDE v1.03 (c) 1997-8 Grant Guenther <grant@torque.net>
1. Introduction
===============
Owing to the simplicity and near universality of the parallel port interface
to personal computers, many external devices such as portable hard-disk,
CD-ROM, LS-120 and tape drives use the parallel port to connect to their
host computer. While some devices (notably scanners) use ad-hoc methods
to pass commands and data through the parallel port interface, most
to pass commands and data through the parallel port interface, most
external devices are actually identical to an internal model, but with
a parallel-port adapter chip added in. Some of the original parallel port
adapters were little more than mechanisms for multiplexing a SCSI bus.
@ -28,47 +30,50 @@ were to open up a parallel port CD-ROM drive, for instance, one would
find a standard ATAPI CD-ROM drive, a power supply, and a single adapter
that interconnected a standard PC parallel port cable and a standard
IDE cable. It is usually possible to exchange the CD-ROM device with
any other device using the IDE interface.
any other device using the IDE interface.
The document describes the support in Linux for parallel port IDE
devices. It does not cover parallel port SCSI devices, "ditto" tape
drives or scanners. Many different devices are supported by the
drives or scanners. Many different devices are supported by the
parallel port IDE subsystem, including:
MicroSolutions backpack CD-ROM
MicroSolutions backpack PD/CD
MicroSolutions backpack hard-drives
MicroSolutions backpack 8000t tape drive
SyQuest EZ-135, EZ-230 & SparQ drives
Avatar Shark
Imation Superdisk LS-120
Maxell Superdisk LS-120
FreeCom Power CD
Hewlett-Packard 5GB and 8GB tape drives
Hewlett-Packard 7100 and 7200 CD-RW drives
- MicroSolutions backpack CD-ROM
- MicroSolutions backpack PD/CD
- MicroSolutions backpack hard-drives
- MicroSolutions backpack 8000t tape drive
- SyQuest EZ-135, EZ-230 & SparQ drives
- Avatar Shark
- Imation Superdisk LS-120
- Maxell Superdisk LS-120
- FreeCom Power CD
- Hewlett-Packard 5GB and 8GB tape drives
- Hewlett-Packard 7100 and 7200 CD-RW drives
as well as most of the clone and no-name products on the market.
To support such a wide range of devices, PARIDE, the parallel port IDE
subsystem, is actually structured in three parts. There is a base
paride module which provides a registry and some common methods for
accessing the parallel ports. The second component is a set of
high-level drivers for each of the different types of supported devices:
accessing the parallel ports. The second component is a set of
high-level drivers for each of the different types of supported devices:
=== =============
pd IDE disk
pcd ATAPI CD-ROM
pf ATAPI disk
pt ATAPI tape
pg ATAPI generic
=== =============
(Currently, the pg driver is only used with CD-R drives).
The high-level drivers function according to the relevant standards.
The third component of PARIDE is a set of low-level protocol drivers
for each of the parallel port IDE adapter chips. Thanks to the interest
and encouragement of Linux users from many parts of the world,
and encouragement of Linux users from many parts of the world,
support is available for almost all known adapter protocols:
==== ====================================== ====
aten ATEN EH-100 (HK)
bpck Microsolutions backpack (US)
comm DataStor (old-type) "commuter" adapter (TW)
@ -83,9 +88,11 @@ support is available for almost all known adapter protocols:
ktti KT Technology PHd adapter (SG)
on20 OnSpec 90c20 (US)
on26 OnSpec 90c26 (US)
==== ====================================== ====
2. Using the PARIDE subsystem
=============================
While configuring the Linux kernel, you may choose either to build
the PARIDE drivers into your kernel, or to build them as modules.
@ -94,10 +101,10 @@ In either case, you will need to select "Parallel port IDE device support"
as well as at least one of the high-level drivers and at least one
of the parallel port communication protocols. If you do not know
what kind of parallel port adapter is used in your drive, you could
begin by checking the file names and any text files on your DOS
begin by checking the file names and any text files on your DOS
installation floppy. Alternatively, you can look at the markings on
the adapter chip itself. That's usually sufficient to identify the
correct device.
correct device.
You can actually select all the protocol modules, and allow the PARIDE
subsystem to try them all for you.
@ -105,8 +112,9 @@ subsystem to try them all for you.
For the "brand-name" products listed above, here are the protocol
and high-level drivers that you would use:
================ ============ ====== ========
Manufacturer Model Driver Protocol
================ ============ ====== ========
MicroSolutions CD-ROM pcd bpck
MicroSolutions PD drive pf bpck
MicroSolutions hard-drive pd bpck
@ -119,8 +127,10 @@ and high-level drivers that you would use:
Hewlett-Packard 5GB Tape pt epat
Hewlett-Packard 7200e (CD) pcd epat
Hewlett-Packard 7200e (CD-R) pg epat
================ ============ ====== ========
2.1 Configuring built-in drivers
---------------------------------
We recommend that you get to know how the drivers work and how to
configure them as loadable modules, before attempting to compile a
@ -143,7 +153,7 @@ protocol identification number and, for some devices, the drive's
chain ID. While your system is booting, a number of messages are
displayed on the console. Like all such messages, they can be
reviewed with the 'dmesg' command. Among those messages will be
some lines like:
some lines like::
paride: bpck registered as protocol 0
paride: epat registered as protocol 1
@ -158,10 +168,10 @@ the last two digits of the drive's serial number (but read MicroSolutions'
documentation about this).
As an example, let's assume that you have a MicroSolutions PD/CD drive
with unit ID number 36 connected to the parallel port at 0x378, a SyQuest
EZ-135 connected to the chained port on the PD/CD drive and also an
Imation Superdisk connected to port 0x278. You could give the following
options on your boot command:
with unit ID number 36 connected to the parallel port at 0x378, a SyQuest
EZ-135 connected to the chained port on the PD/CD drive and also an
Imation Superdisk connected to port 0x278. You could give the following
options on your boot command::
pd.drive0=0x378,1 pf.drive0=0x278,1 pf.drive1=0x378,0,36
@ -169,24 +179,27 @@ In the last option, pf.drive1 configures device /dev/pf1, the 0x378
is the parallel port base address, the 0 is the protocol registration
number and 36 is the chain ID.
Please note: while PARIDE will work both with and without the
Please note: while PARIDE will work both with and without the
PARPORT parallel port sharing system that is included by the
"Parallel port support" option, PARPORT must be included and enabled
if you want to use chains of devices on the same parallel port.
2.2 Loading and configuring PARIDE as modules
----------------------------------------------
It is much faster and simpler to get to understand the PARIDE drivers
if you use them as loadable kernel modules.
if you use them as loadable kernel modules.
Note 1: using these drivers with the "kerneld" automatic module loading
system is not recommended for beginners, and is not documented here.
Note 1:
using these drivers with the "kerneld" automatic module loading
system is not recommended for beginners, and is not documented here.
Note 2: if you build PARPORT support as a loadable module, PARIDE must
also be built as loadable modules, and PARPORT must be loaded before the
PARIDE modules.
Note 2:
if you build PARPORT support as a loadable module, PARIDE must
also be built as loadable modules, and PARPORT must be loaded before
the PARIDE modules.
To use PARIDE, you must begin by
To use PARIDE, you must begin by::
insmod paride
@ -195,8 +208,8 @@ among other tasks.
Then, load as many of the protocol modules as you think you might need.
As you load each module, it will register the protocols that it supports,
and print a log message to your kernel log file and your console. For
example:
and print a log message to your kernel log file and your console. For
example::
# insmod epat
paride: epat registered as protocol 0
@ -205,22 +218,22 @@ example:
paride: k971 registered as protocol 2
Finally, you can load high-level drivers for each kind of device that
you have connected. By default, each driver will autoprobe for a single
you have connected. By default, each driver will autoprobe for a single
device, but you can support up to four similar devices by giving their
individual co-ordinates when you load the driver.
For example, if you had two no-name CD-ROM drives both using the
KingByte KBIC-951A adapter, one on port 0x378 and the other on 0x3bc
you could give the following command:
you could give the following command::
# insmod pcd drive0=0x378,1 drive1=0x3bc,1
For most adapters, giving a port address and protocol number is sufficient,
but check the source files in linux/drivers/block/paride for more
but check the source files in linux/drivers/block/paride for more
information. (Hopefully someone will write some man pages one day !).
As another example, here's what happens when PARPORT is installed, and
a SyQuest EZ-135 is attached to port 0x378:
a SyQuest EZ-135 is attached to port 0x378::
# insmod paride
paride: version 1.0 installed
@ -237,46 +250,47 @@ Note that the last line is the output from the generic partition table
scanner - in this case it reports that it has found a disk with one partition.
2.3 Using a PARIDE device
--------------------------
Once the drivers have been loaded, you can access PARIDE devices in the
same way as their traditional counterparts. You will probably need to
create the device "special files". Here is a simple script that you can
cut to a file and execute:
cut to a file and execute::
#!/bin/bash
#
# mkd -- a script to create the device special files for the PARIDE subsystem
#
function mkdev {
mknod $1 $2 $3 $4 ; chmod 0660 $1 ; chown root:disk $1
}
#
function pd {
D=$( printf \\$( printf "x%03x" $[ $1 + 97 ] ) )
mkdev pd$D b 45 $[ $1 * 16 ]
for P in 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
do mkdev pd$D$P b 45 $[ $1 * 16 + $P ]
done
}
#
cd /dev
#
for u in 0 1 2 3 ; do pd $u ; done
for u in 0 1 2 3 ; do mkdev pcd$u b 46 $u ; done
for u in 0 1 2 3 ; do mkdev pf$u b 47 $u ; done
for u in 0 1 2 3 ; do mkdev pt$u c 96 $u ; done
for u in 0 1 2 3 ; do mkdev npt$u c 96 $[ $u + 128 ] ; done
for u in 0 1 2 3 ; do mkdev pg$u c 97 $u ; done
#
# end of mkd
#!/bin/bash
#
# mkd -- a script to create the device special files for the PARIDE subsystem
#
function mkdev {
mknod $1 $2 $3 $4 ; chmod 0660 $1 ; chown root:disk $1
}
#
function pd {
D=$( printf \\$( printf "x%03x" $[ $1 + 97 ] ) )
mkdev pd$D b 45 $[ $1 * 16 ]
for P in 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
do mkdev pd$D$P b 45 $[ $1 * 16 + $P ]
done
}
#
cd /dev
#
for u in 0 1 2 3 ; do pd $u ; done
for u in 0 1 2 3 ; do mkdev pcd$u b 46 $u ; done
for u in 0 1 2 3 ; do mkdev pf$u b 47 $u ; done
for u in 0 1 2 3 ; do mkdev pt$u c 96 $u ; done
for u in 0 1 2 3 ; do mkdev npt$u c 96 $[ $u + 128 ] ; done
for u in 0 1 2 3 ; do mkdev pg$u c 97 $u ; done
#
# end of mkd
With the device files and drivers in place, you can access PARIDE devices
like any other Linux device. For example, to mount a CD-ROM in pcd0, use:
like any other Linux device. For example, to mount a CD-ROM in pcd0, use::
mount /dev/pcd0 /cdrom
If you have a fresh Avatar Shark cartridge, and the drive is pda, you
might do something like:
might do something like::
fdisk /dev/pda -- make a new partition table with
partition 1 of type 83
@ -289,41 +303,46 @@ might do something like:
Devices like the Imation superdisk work in the same way, except that
they do not have a partition table. For example to make a 120MB
floppy that you could share with a DOS system:
floppy that you could share with a DOS system::
mkdosfs /dev/pf0
mount /dev/pf0 /mnt
2.4 The pf driver
------------------
The pf driver is intended for use with parallel port ATAPI disk
devices. The most common devices in this category are PD drives
and LS-120 drives. Traditionally, media for these devices are not
partitioned. Consequently, the pf driver does not support partitioned
media. This may be changed in a future version of the driver.
media. This may be changed in a future version of the driver.
2.5 Using the pt driver
------------------------
The pt driver for parallel port ATAPI tape drives is a minimal driver.
It does not yet support many of the standard tape ioctl operations.
It does not yet support many of the standard tape ioctl operations.
For best performance, a block size of 32KB should be used. You will
probably want to set the parallel port delay to 0, if you can.
2.6 Using the pg driver
------------------------
The pg driver can be used in conjunction with the cdrecord program
to create CD-ROMs. Please get cdrecord version 1.6.1 or later
from ftp://ftp.fokus.gmd.de/pub/unix/cdrecord/ . To record CD-R media
your parallel port should ideally be set to EPP mode, and the "port delay"
should be set to 0. With those settings it is possible to record at 2x
from ftp://ftp.fokus.gmd.de/pub/unix/cdrecord/ . To record CD-R media
your parallel port should ideally be set to EPP mode, and the "port delay"
should be set to 0. With those settings it is possible to record at 2x
speed without any buffer underruns. If you cannot get the driver to work
in EPP mode, try to use "bidirectional" or "PS/2" mode and 1x speeds only.
3. Troubleshooting
==================
3.1 Use EPP mode if you can
----------------------------
The most common problems that people report with the PARIDE drivers
concern the parallel port CMOS settings. At this time, none of the
@ -332,6 +351,7 @@ If you are able to do so, please set your parallel port into EPP mode
using your CMOS setup procedure.
3.2 Check the port delay
-------------------------
Some parallel ports cannot reliably transfer data at full speed. To
offset the errors, the PARIDE protocol modules introduce a "port
@ -347,23 +367,25 @@ read the comments at the beginning of the driver source files in
linux/drivers/block/paride.
3.3 Some drives need a printer reset
-------------------------------------
There appear to be a number of "noname" external drives on the market
that do not always power up correctly. We have noticed this with some
drives based on OnSpec and older Freecom adapters. In these rare cases,
the adapter can often be reinitialised by issuing a "printer reset" on
the parallel port. As the reset operation is potentially disruptive in
multiple device environments, the PARIDE drivers will not do it
automatically. You can however, force a printer reset by doing:
the parallel port. As the reset operation is potentially disruptive in
multiple device environments, the PARIDE drivers will not do it
automatically. You can however, force a printer reset by doing::
insmod lp reset=1
rmmod lp
If you have one of these marginal cases, you should probably build
your paride drivers as modules, and arrange to do the printer reset
before loading the PARIDE drivers.
before loading the PARIDE drivers.
3.4 Use the verbose option and dmesg if you need help
------------------------------------------------------
While a lot of testing has gone into these drivers to make them work
as smoothly as possible, problems will arise. If you do have problems,
@ -373,7 +395,7 @@ clues, then please make sure that only one drive is hooked to your system,
and that either (a) PARPORT is enabled or (b) no other device driver
is using your parallel port (check in /proc/ioports). Then, load the
appropriate drivers (you can load several protocol modules if you want)
as in:
as in::
# insmod paride
# insmod epat
@ -394,12 +416,14 @@ by e-mail to grant@torque.net, or join the linux-parport mailing list
and post your report there.
3.5 For more information or help
---------------------------------
You can join the linux-parport mailing list by sending a mail message
to
to:
linux-parport-request@torque.net
with the single word
with the single word::
subscribe
@ -412,6 +436,4 @@ have in your mail headers, when sending mail to the list server.
You might also find some useful information on the linux-parport
web pages (although they are not always up to date) at
http://web.archive.org/web/*/http://www.torque.net/parport/
http://web.archive.org/web/%2E/http://www.torque.net/parport/

55
Documentation/blockdev/ramdisk.txt → Documentation/admin-guide/blockdev/ramdisk.rst
View File

@ -1,7 +1,8 @@
==========================================
Using the RAM disk block device with Linux
------------------------------------------
==========================================
Contents:
.. Contents:
1) Overview
2) Kernel Command Line Parameters
@ -42,7 +43,7 @@ rescue floppy disk.
2a) Kernel Command Line Parameters
ramdisk_size=N
==============
Size of the ramdisk.
This parameter tells the RAM disk driver to set up RAM disks of N k size. The
default is 4096 (4 MB).
@ -50,16 +51,13 @@ default is 4096 (4 MB).
2b) Module parameters
rd_nr
=====
/dev/ramX devices created.
/dev/ramX devices created.
max_part
========
Maximum partition number.
Maximum partition number.
rd_size
=======
See ramdisk_size.
See ramdisk_size.
3) Using "rdev -r"
------------------
@ -71,11 +69,11 @@ to 2 MB (2^11) of where to find the RAM disk (this used to be the size). Bit
prompt/wait sequence is to be given before trying to read the RAM disk. Since
the RAM disk dynamically grows as data is being written into it, a size field
is not required. Bits 11 to 13 are not currently used and may as well be zero.
These numbers are no magical secrets, as seen below:
These numbers are no magical secrets, as seen below::
./arch/x86/kernel/setup.c:#define RAMDISK_IMAGE_START_MASK 0x07FF
./arch/x86/kernel/setup.c:#define RAMDISK_PROMPT_FLAG 0x8000
./arch/x86/kernel/setup.c:#define RAMDISK_LOAD_FLAG 0x4000
./arch/x86/kernel/setup.c:#define RAMDISK_IMAGE_START_MASK 0x07FF
./arch/x86/kernel/setup.c:#define RAMDISK_PROMPT_FLAG 0x8000
./arch/x86/kernel/setup.c:#define RAMDISK_LOAD_FLAG 0x4000
Consider a typical two floppy disk setup, where you will have the
kernel on disk one, and have already put a RAM disk image onto disk #2.
@ -92,20 +90,23 @@ sequence so that you have a chance to switch floppy disks.
The command line equivalent is: "prompt_ramdisk=1"
Putting that together gives 2^15 + 2^14 + 0 = 49152 for an rdev word.
So to create disk one of the set, you would do:
So to create disk one of the set, you would do::
/usr/src/linux# cat arch/x86/boot/zImage > /dev/fd0
/usr/src/linux# rdev /dev/fd0 /dev/fd0
/usr/src/linux# rdev -r /dev/fd0 49152
If you make a boot disk that has LILO, then for the above, you would use:
If you make a boot disk that has LILO, then for the above, you would use::
append = "ramdisk_start=0 load_ramdisk=1 prompt_ramdisk=1"
Since the default start = 0 and the default prompt = 1, you could use:
Since the default start = 0 and the default prompt = 1, you could use::
append = "load_ramdisk=1"
4) An Example of Creating a Compressed RAM Disk
----------------------------------------------
-----------------------------------------------
To create a RAM disk image, you will need a spare block device to
construct it on. This can be the RAM disk device itself, or an
@ -120,11 +121,11 @@ a) Decide on the RAM disk size that you want. Say 2 MB for this example.
Create it by writing to the RAM disk device. (This step is not currently
required, but may be in the future.) It is wise to zero out the
area (esp. for disks) so that maximal compression is achieved for
the unused blocks of the image that you are about to create.
the unused blocks of the image that you are about to create::
dd if=/dev/zero of=/dev/ram0 bs=1k count=2048
b) Make a filesystem on it. Say ext2fs for this example.
b) Make a filesystem on it. Say ext2fs for this example::
mke2fs -vm0 /dev/ram0 2048
@ -133,11 +134,11 @@ c) Mount it, copy the files you want to it (eg: /etc/* /dev/* ...)
d) Compress the contents of the RAM disk. The level of compression
will be approximately 50% of the space used by the files. Unused
space on the RAM disk will compress to almost nothing.
space on the RAM disk will compress to almost nothing::
dd if=/dev/ram0 bs=1k count=2048 | gzip -v9 > /tmp/ram_image.gz
e) Put the kernel onto the floppy
e) Put the kernel onto the floppy::
dd if=zImage of=/dev/fd0 bs=1k
@ -146,13 +147,13 @@ f) Put the RAM disk image onto the floppy, after the kernel. Use an offset
(possibly larger) kernel onto the same floppy later without overlapping
the RAM disk image. An offset of 400 kB for kernels about 350 kB in
size would be reasonable. Make sure offset+size of ram_image.gz is
not larger than the total space on your floppy (usually 1440 kB).
not larger than the total space on your floppy (usually 1440 kB)::
dd if=/tmp/ram_image.gz of=/dev/fd0 bs=1k seek=400
g) Use "rdev" to set the boot device, RAM disk offset, prompt flag, etc.
For prompt_ramdisk=1, load_ramdisk=1, ramdisk_start=400, one would
have 2^15 + 2^14 + 400 = 49552.
have 2^15 + 2^14 + 400 = 49552::
rdev /dev/fd0 /dev/fd0
rdev -r /dev/fd0 49552
@ -160,15 +161,17 @@ g) Use "rdev" to set the boot device, RAM disk offset, prompt flag, etc.
That is it. You now have your boot/root compressed RAM disk floppy. Some
users may wish to combine steps (d) and (f) by using a pipe.
--------------------------------------------------------------------------
Paul Gortmaker 12/95
Changelog:
----------
10-22-04 : Updated to reflect changes in command line options, remove
10-22-04 :
Updated to reflect changes in command line options, remove
obsolete references, general cleanup.
James Nelson (james4765@gmail.com)
12-95 : Original Document
12-95 :
Original Document

197
Documentation/blockdev/zram.txt → Documentation/admin-guide/blockdev/zram.rst
View File

@ -1,7 +1,9 @@
========================================
zram: Compressed RAM based block devices
----------------------------------------
========================================
* Introduction
Introduction
============
The zram module creates RAM based block devices named /dev/zram<id>
(<id> = 0, 1, ...). Pages written to these disks are compressed and stored
@ -12,9 +14,11 @@ use as swap disks, various caches under /var and maybe many more :)
Statistics for individual zram devices are exported through sysfs nodes at
/sys/block/zram<id>/
* Usage
Usage
=====
There are several ways to configure and manage zram device(-s):
a) using zram and zram_control sysfs attributes
b) using zramctl utility, provided by util-linux (util-linux@vger.kernel.org).
@ -22,7 +26,7 @@ In this document we will describe only 'manual' zram configuration steps,
IOW, zram and zram_control sysfs attributes.
In order to get a better idea about zramctl please consult util-linux
documentation, zramctl man-page or `zramctl --help'. Please be informed
documentation, zramctl man-page or `zramctl --help`. Please be informed
that zram maintainers do not develop/maintain util-linux or zramctl, should
you have any questions please contact util-linux@vger.kernel.org
@ -30,19 +34,23 @@ Following shows a typical sequence of steps for using zram.
WARNING
=======
For the sake of simplicity we skip error checking parts in most of the
examples below. However, it is your sole responsibility to handle errors.
zram sysfs attributes always return negative values in case of errors.
The list of possible return codes:
-EBUSY -- an attempt to modify an attribute that cannot be changed once
the device has been initialised. Please reset device first;
-ENOMEM -- zram was not able to allocate enough memory to fulfil your
needs;
-EINVAL -- invalid input has been provided.
======== =============================================================
-EBUSY an attempt to modify an attribute that cannot be changed once
the device has been initialised. Please reset device first;
-ENOMEM zram was not able to allocate enough memory to fulfil your
needs;
-EINVAL invalid input has been provided.
======== =============================================================
If you use 'echo', the returned value that is changed by 'echo' utility,
and, in general case, something like:
and, in general case, something like::
echo 3 > /sys/block/zram0/max_comp_streams
if [ $? -ne 0 ];
@ -51,7 +59,11 @@ and, in general case, something like:
should suffice.
1) Load Module:
1) Load Module
==============
::
modprobe zram num_devices=4
This creates 4 devices: /dev/zram{0,1,2,3}
@ -59,6 +71,8 @@ num_devices parameter is optional and tells zram how many devices should be
pre-created. Default: 1.
2) Set max number of compression streams
========================================
Regardless the value passed to this attribute, ZRAM will always
allocate multiple compression streams - one per online CPUs - thus
allowing several concurrent compression operations. The number of
@ -66,16 +80,20 @@ allocated compression streams goes down when some of the CPUs
become offline. There is no single-compression-stream mode anymore,
unless you are running a UP system or has only 1 CPU online.
To find out how many streams are currently available:
To find out how many streams are currently available::
cat /sys/block/zram0/max_comp_streams
3) Select compression algorithm
===============================
Using comp_algorithm device attribute one can see available and
currently selected (shown in square brackets) compression algorithms,
change selected compression algorithm (once the device is initialised
there is no way to change compression algorithm).
Examples:
Examples::
#show supported compression algorithms
cat /sys/block/zram0/comp_algorithm
lzo [lz4]
@ -83,20 +101,23 @@ Examples:
#select lzo compression algorithm
echo lzo > /sys/block/zram0/comp_algorithm
For the time being, the `comp_algorithm' content does not necessarily
For the time being, the `comp_algorithm` content does not necessarily
show every compression algorithm supported by the kernel. We keep this
list primarily to simplify device configuration and one can configure
a new device with a compression algorithm that is not listed in
`comp_algorithm'. The thing is that, internally, ZRAM uses Crypto API
`comp_algorithm`. The thing is that, internally, ZRAM uses Crypto API
and, if some of the algorithms were built as modules, it's impossible
to list all of them using, for instance, /proc/crypto or any other
method. This, however, has an advantage of permitting the usage of
custom crypto compression modules (implementing S/W or H/W compression).
4) Set Disksize
===============
Set disk size by writing the value to sysfs node 'disksize'.
The value can be either in bytes or you can use mem suffixes.
Examples:
Examples::
# Initialize /dev/zram0 with 50MB disksize
echo $((50*1024*1024)) > /sys/block/zram0/disksize
@ -111,10 +132,13 @@ since we expect a 2:1 compression ratio. Note that zram uses about 0.1% of the
size of the disk when not in use so a huge zram is wasteful.
5) Set memory limit: Optional
=============================
Set memory limit by writing the value to sysfs node 'mem_limit'.
The value can be either in bytes or you can use mem suffixes.
In addition, you could change the value in runtime.
Examples:
Examples::
# limit /dev/zram0 with 50MB memory
echo $((50*1024*1024)) > /sys/block/zram0/mem_limit
@ -126,7 +150,11 @@ Examples:
# To disable memory limit
echo 0 > /sys/block/zram0/mem_limit
6) Activate:
6) Activate
===========
::
mkswap /dev/zram0
swapon /dev/zram0
@ -134,6 +162,7 @@ Examples:
mount /dev/zram1 /tmp
7) Add/remove zram devices
==========================
zram provides a control interface, which enables dynamic (on-demand) device
addition and removal.
@ -142,44 +171,51 @@ In order to add a new /dev/zramX device, perform read operation on hot_add
attribute. This will return either new device's device id (meaning that you
can use /dev/zram<id>) or error code.
Example:
Example::
cat /sys/class/zram-control/hot_add
1
To remove the existing /dev/zramX device (where X is a device id)
execute
execute::
echo X > /sys/class/zram-control/hot_remove
8) Stats:
8) Stats
========
Per-device statistics are exported as various nodes under /sys/block/zram<id>/
A brief description of exported device attributes. For more details please
read Documentation/ABI/testing/sysfs-block-zram.
====================== ====== ===============================================
Name access description
---- ------ -----------
====================== ====== ===============================================
disksize RW show and set the device's disk size
initstate RO shows the initialization state of the device
reset WO trigger device reset
mem_used_max WO reset the `mem_used_max' counter (see later)
mem_limit WO specifies the maximum amount of memory ZRAM can use
to store the compressed data
writeback_limit WO specifies the maximum amount of write IO zram can
write out to backing device as 4KB unit
mem_used_max WO reset the `mem_used_max` counter (see later)
mem_limit WO specifies the maximum amount of memory ZRAM can
use to store the compressed data
writeback_limit WO specifies the maximum amount of write IO zram
can write out to backing device as 4KB unit
writeback_limit_enable RW show and set writeback_limit feature
max_comp_streams RW the number of possible concurrent compress operations
max_comp_streams RW the number of possible concurrent compress
operations
comp_algorithm RW show and change the compression algorithm
compact WO trigger memory compaction
debug_stat RO this file is used for zram debugging purposes
backing_dev RW set up backend storage for zram to write out
idle WO mark allocated slot as idle
====================== ====== ===============================================
User space is advised to use the following files to read the device statistics.
File /sys/block/zram<id>/stat
Represents block layer statistics. Read Documentation/block/stat.txt for
Represents block layer statistics. Read Documentation/block/stat.rst for
details.
File /sys/block/zram<id>/io_stat
@ -188,23 +224,31 @@ The stat file represents device's I/O statistics not accounted by block
layer and, thus, not available in zram<id>/stat file. It consists of a
single line of text and contains the following stats separated by
whitespace:
failed_reads the number of failed reads
failed_writes the number of failed writes
invalid_io the number of non-page-size-aligned I/O requests
============= =============================================================
failed_reads The number of failed reads
failed_writes The number of failed writes
invalid_io The number of non-page-size-aligned I/O requests
notify_free Depending on device usage scenario it may account
a) the number of pages freed because of swap slot free
notifications or b) the number of pages freed because of
REQ_OP_DISCARD requests sent by bio. The former ones are
sent to a swap block device when a swap slot is freed,
which implies that this disk is being used as a swap disk.
notifications
b) the number of pages freed because of
REQ_OP_DISCARD requests sent by bio. The former ones are
sent to a swap block device when a swap slot is freed,
which implies that this disk is being used as a swap disk.
The latter ones are sent by filesystem mounted with
discard option, whenever some data blocks are getting
discarded.
============= =============================================================
File /sys/block/zram<id>/mm_stat
The stat file represents device's mm statistics. It consists of a single
line of text and contains the following stats separated by whitespace:
================ =============================================================
orig_data_size uncompressed size of data stored in this disk.
This excludes same-element-filled pages (same_pages) since
no memory is allocated for them.
@ -223,58 +267,71 @@ line of text and contains the following stats separated by whitespace:
No memory is allocated for such pages.
pages_compacted the number of pages freed during compaction
huge_pages the number of incompressible pages
================ =============================================================
File /sys/block/zram<id>/bd_stat
The stat file represents device's backing device statistics. It consists of
a single line of text and contains the following stats separated by whitespace:
============== =============================================================
bd_count size of data written in backing device.
Unit: 4K bytes
bd_reads the number of reads from backing device
Unit: 4K bytes
bd_writes the number of writes to backing device
Unit: 4K bytes
============== =============================================================
9) Deactivate
=============
::
9) Deactivate:
swapoff /dev/zram0
umount /dev/zram1
10) Reset:
Write any positive value to 'reset' sysfs node
echo 1 > /sys/block/zram0/reset
echo 1 > /sys/block/zram1/reset
10) Reset
=========
Write any positive value to 'reset' sysfs node::
echo 1 > /sys/block/zram0/reset
echo 1 > /sys/block/zram1/reset
This frees all the memory allocated for the given device and
resets the disksize to zero. You must set the disksize again
before reusing the device.
* Optional Feature
Optional Feature
================
= writeback
writeback
---------
With CONFIG_ZRAM_WRITEBACK, zram can write idle/incompressible page
to backing storage rather than keeping it in memory.
To use the feature, admin should set up backing device via
To use the feature, admin should set up backing device via::
"echo /dev/sda5 > /sys/block/zramX/backing_dev"
echo /dev/sda5 > /sys/block/zramX/backing_dev
before disksize setting. It supports only partition at this moment.
If admin want to use incompressible page writeback, they could do via
If admin want to use incompressible page writeback, they could do via::
"echo huge > /sys/block/zramX/write"
echo huge > /sys/block/zramX/write
To use idle page writeback, first, user need to declare zram pages
as idle.
as idle::
"echo all > /sys/block/zramX/idle"
echo all > /sys/block/zramX/idle
From now on, any pages on zram are idle pages. The idle mark
will be removed until someone request access of the block.
IOW, unless there is access request, those pages are still idle pages.
Admin can request writeback of those idle pages at right timing via
Admin can request writeback of those idle pages at right timing via::
"echo idle > /sys/block/zramX/writeback"
echo idle > /sys/block/zramX/writeback
With the command, zram writeback idle pages from memory to the storage.
@ -285,7 +342,7 @@ to guarantee storage health for entire product life.
To overcome the concern, zram supports "writeback_limit" feature.
The "writeback_limit_enable"'s default value is 0 so that it doesn't limit
any writeback. IOW, if admin want to apply writeback budget, he should
enable writeback_limit_enable via
enable writeback_limit_enable via::
$ echo 1 > /sys/block/zramX/writeback_limit_enable
@ -296,7 +353,7 @@ until admin set the budget via /sys/block/zramX/writeback_limit.
assigned via /sys/block/zramX/writeback_limit is meaninless.)
If admin want to limit writeback as per-day 400M, he could do it
like below.
like below::
$ MB_SHIFT=20
$ 4K_SHIFT=12
@ -305,16 +362,16 @@ like below.
$ echo 1 > /sys/block/zram0/writeback_limit_enable
If admin want to allow further write again once the bugdet is exausted,
he could do it like below
he could do it like below::
$ echo $((400<<MB_SHIFT>>4K_SHIFT)) > \
/sys/block/zram0/writeback_limit
If admin want to see remaining writeback budget since he set,
If admin want to see remaining writeback budget since he set::
$ cat /sys/block/zramX/writeback_limit
If admin want to disable writeback limit, he could do
If admin want to disable writeback limit, he could do::
$ echo 0 > /sys/block/zramX/writeback_limit_enable
@ -326,25 +383,35 @@ budget in next setting is user's job.
If admin want to measure writeback count in a certain period, he could
know it via /sys/block/zram0/bd_stat's 3rd column.
= memory tracking
memory tracking
===============
With CONFIG_ZRAM_MEMORY_TRACKING, user can know information of the
zram block. It could be useful to catch cold or incompressible
pages of the process with*pagemap.
If you enable the feature, you could see block state via
/sys/kernel/debug/zram/zram0/block_state". The output is as follows,
/sys/kernel/debug/zram/zram0/block_state". The output is as follows::
300 75.033841 .wh.
301 63.806904 s...
302 63.806919 ..hi
First column is zram's block index.
Second column is access time since the system was booted
Third column is state of the block.
(s: same page
w: written page to backing store
h: huge page
i: idle page)
First column
zram's block index.
Second column
access time since the system was booted
Third column
state of the block:
s:
same page
w:
written page to backing store
h:
huge page
i:
idle page
First line of above example says 300th block is accessed at 75.033841sec
and the block's state is huge so it is written back to the backing

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@ -90,9 +90,9 @@ the disk is not available then you have three options:
run a null modem to a second machine and capture the output there
using your favourite communication program. Minicom works well.
(3) Use Kdump (see Documentation/kdump/kdump.rst),
(3) Use Kdump (see Documentation/admin-guide/kdump/kdump.rst),
extract the kernel ring buffer from old memory with using dmesg
gdbmacro in Documentation/kdump/gdbmacros.txt.
gdbmacro in Documentation/admin-guide/kdump/gdbmacros.txt.
Finding the bug's location
--------------------------

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@ -3,7 +3,7 @@ Control Groups
==============
Written by Paul Menage <menage@google.com> based on
Documentation/cgroup-v1/cpusets.rst
Documentation/admin-guide/cgroup-v1/cpusets.rst
Original copyright statements from cpusets.txt:
@ -76,7 +76,7 @@ On their own, the only use for cgroups is for simple job
tracking. The intention is that other subsystems hook into the generic
cgroup support to provide new attributes for cgroups, such as
accounting/limiting the resources which processes in a cgroup can
access. For example, cpusets (see Documentation/cgroup-v1/cpusets.rst) allow
access. For example, cpusets (see Documentation/admin-guide/cgroup-v1/cpusets.rst) allow
you to associate a set of CPUs and a set of memory nodes with the
tasks in each cgroup.

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@ -49,7 +49,7 @@ hooks, beyond what is already present, required to manage dynamic
job placement on large systems.
Cpusets use the generic cgroup subsystem described in
Documentation/cgroup-v1/cgroups.rst.
Documentation/admin-guide/cgroup-v1/cgroups.rst.
Requests by a task, using the sched_setaffinity(2) system call to
include CPUs in its CPU affinity mask, and using the mbind(2) and

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@ -1,5 +1,3 @@
:orphan:
========================
Control Groups version 1
========================

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@ -10,7 +10,7 @@ Because VM is getting complex (one of reasons is memcg...), memcg's behavior
is complex. This is a document for memcg's internal behavior.
Please note that implementation details can be changed.
(*) Topics on API should be in Documentation/cgroup-v1/memory.rst)
(*) Topics on API should be in Documentation/admin-guide/cgroup-v1/memory.rst)
0. How to record usage ?
========================
@ -327,7 +327,7 @@ Under below explanation, we assume CONFIG_MEM_RES_CTRL_SWAP=y.
You can see charges have been moved by reading ``*.usage_in_bytes`` or
memory.stat of both A and B.
See 8.2 of Documentation/cgroup-v1/memory.rst to see what value should
See 8.2 of Documentation/admin-guide/cgroup-v1/memory.rst to see what value should
be written to move_charge_at_immigrate.
9.10 Memory thresholds

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@ -9,7 +9,7 @@ This is the authoritative documentation on the design, interface and
conventions of cgroup v2. It describes all userland-visible aspects
of cgroup including core and specific controller behaviors. All
future changes must be reflected in this document. Documentation for
v1 is available under Documentation/cgroup-v1/.
v1 is available under Documentation/admin-guide/cgroup-v1/.
.. CONTENTS
@ -1014,7 +1014,7 @@ All time durations are in microseconds.
A read-only nested-key file which exists on non-root cgroups.
Shows pressure stall information for CPU. See
Documentation/accounting/psi.txt for details.
Documentation/accounting/psi.rst for details.
Memory
@ -1355,7 +1355,7 @@ PAGE_SIZE multiple when read back.
A read-only nested-key file which exists on non-root cgroups.
Shows pressure stall information for memory. See
Documentation/accounting/psi.txt for details.
Documentation/accounting/psi.rst for details.
Usage Guidelines
@ -1498,7 +1498,7 @@ IO Interface Files
A read-only nested-key file which exists on non-root cgroups.
Shows pressure stall information for IO. See
Documentation/accounting/psi.txt for details.
Documentation/accounting/psi.rst for details.
Writeback
@ -2124,7 +2124,7 @@ following two functions.
a queue (device) has been associated with the bio and
before submission.
wbc_account_io(@wbc, @page, @bytes)
wbc_account_cgroup_owner(@wbc, @page, @bytes)
Should be called for each data segment being written out.
While this function doesn't care exactly when it's called
during the writeback session, it's the easiest and most

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@ -1,5 +1,3 @@
:orphan:
=============
Device Mapper
=============

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