The Userspace I/O HOWTO
Hans-Jürgen
Koch
Linux developer, Linutronix
Linutronix
hjk@linutronix.de
2006-12-11
This HOWTO describes concept and usage of Linux kernel's
Userspace I/O system.
0.3
2007-04-29
hjk
Added section about userspace drivers.
0.2
2007-02-13
hjk
Update after multiple mappings were added.
0.1
2006-12-11
hjk
First draft.
About this document
Copyright and License
Copyright (c) 2006 by Hans-Jürgen Koch.
This documentation is Free Software licensed under the terms of the
GPL version 2.
Translations
If you know of any translations for this document, or you are
interested in translating it, please email me
hjk@linutronix.de.
Preface
For many types of devices, creating a Linux kernel driver is
overkill. All that is really needed is some way to handle an
interrupt and provide access to the memory space of the
device. The logic of controlling the device does not
necessarily have to be within the kernel, as the device does
not need to take advantage of any of other resources that the
kernel provides. One such common class of devices that are
like this are for industrial I/O cards.
To address this situation, the userspace I/O system (UIO) was
designed. For typical industrial I/O cards, only a very small
kernel module is needed. The main part of the driver will run in
user space. This simplifies development and reduces the risk of
serious bugs within a kernel module.
Acknowledgments
I'd like to thank Thomas Gleixner and Benedikt Spranger of
Linutronix, who have not only written most of the UIO code, but also
helped greatly writing this HOWTO by giving me all kinds of background
information.
Feedback
Find something wrong with this document? (Or perhaps something
right?) I would love to hear from you. Please email me at
hjk@linutronix.de.
About UIO
If you use UIO for your card's driver, here's what you get:
only one small kernel module to write and maintain.
develop the main part of your driver in user space,
with all the tools and libraries you're used to.
bugs in your driver won't crash the kernel.
updates of your driver can take place without recompiling
the kernel.
if you need to keep some parts of your driver closed source,
you can do so without violating the GPL license on the kernel.
How UIO works
Each UIO device is accessed through a device file and several
sysfs attribute files. The device file will be called
/dev/uio0 for the first device, and
/dev/uio1, /dev/uio2
and so on for subsequent devices.
/dev/uioX is used to access the
address space of the card. Just use
mmap() to access registers or RAM
locations of your card.
Interrupts are handled by reading from
/dev/uioX. A blocking
read() from
/dev/uioX will return as soon as an
interrupt occurs. You can also use
select() on
/dev/uioX to wait for an interrupt. The
integer value read from /dev/uioX
represents the total interrupt count. You can use this number
to figure out if you missed some interrupts.
To handle interrupts properly, your custom kernel module can
provide its own interrupt handler. It will automatically be
called by the built-in handler.
For cards that don't generate interrupts but need to be
polled, there is the possibility to set up a timer that
triggers the interrupt handler at configurable time intervals.
See drivers/uio/uio_dummy.c for an
example of this technique.
Each driver provides attributes that are used to read or write
variables. These attributes are accessible through sysfs
files. A custom kernel driver module can add its own
attributes to the device owned by the uio driver, but not added
to the UIO device itself at this time. This might change in the
future if it would be found to be useful.
The following standard attributes are provided by the UIO
framework:
name: The name of your device. It is
recommended to use the name of your kernel module for this.
version: A version string defined by your
driver. This allows the user space part of your driver to deal
with different versions of the kernel module.
event: The total number of interrupts
handled by the driver since the last time the device node was
read.
These attributes appear under the
/sys/class/uio/uioX directory. Please
note that this directory might be a symlink, and not a real
directory. Any userspace code that accesses it must be able
to handle this.
Each UIO device can make one or more memory regions available for
memory mapping. This is necessary because some industrial I/O cards
require access to more than one PCI memory region in a driver.
Each mapping has its own directory in sysfs, the first mapping
appears as /sys/class/uio/uioX/maps/map0/.
Subsequent mappings create directories map1/,
map2/, and so on. These directories will only
appear if the size of the mapping is not 0.
Each mapX/ directory contains two read-only files
that show start address and size of the memory:
addr: The address of memory that can be mapped.
size: The size, in bytes, of the memory
pointed to by addr.
From userspace, the different mappings are distinguished by adjusting
the offset parameter of the
mmap() call. To map the memory of mapping N, you
have to use N times the page size as your offset:
offset = N * getpagesize();
Using uio_dummy
Well, there is no real use for uio_dummy. Its only purpose is
to test most parts of the UIO system (everything except
hardware interrupts), and to serve as an example for the
kernel module that you will have to write yourself.
What uio_dummy does
The kernel module uio_dummy.ko creates a
device that uses a timer to generate periodic interrupts. The
interrupt handler does nothing but increment a counter. The
driver adds two custom attributes, count
and freq, that appear under
/sys/devices/platform/uio_dummy/.
The attribute count can be read and
written. The associated file
/sys/devices/platform/uio_dummy/count
appears as a normal text file and contains the total number of
timer interrupts. If you look at it (e.g. using
cat), you'll notice it is slowly counting
up.
The attribute freq can be read and written.
The content of
/sys/devices/platform/uio_dummy/freq
represents the number of system timer ticks between two timer
interrupts. The default value of freq is
the value of the kernel variable HZ, which
gives you an interval of one second. Lower values will
increase the frequency. Try the following:
cd /sys/devices/platform/uio_dummy/
echo 100 > freq
Use cat count to see how the interrupt
frequency changes.
Writing your own kernel module
Please have a look at uio_dummy.c as an
example. The following paragraphs explain the different
sections of this file.
struct uio_info
This structure tells the framework the details of your driver,
Some of the members are required, others are optional.
char *name: Required. The name of your driver as
it will appear in sysfs. I recommend using the name of your module for this.
char *version: Required. This string appears in
/sys/class/uio/uioX/version.
struct uio_mem mem[ MAX_UIO_MAPS ]: Required if you
have memory that can be mapped with mmap(). For each
mapping you need to fill one of the uio_mem structures.
See the description below for details.
long irq: Required. If your hardware generates an
interrupt, it's your modules task to determine the irq number during
initialization. If you don't have a hardware generated interrupt but
want to trigger the interrupt handler in some other way, set
irq to UIO_IRQ_CUSTOM. The
uio_dummy module does this as it triggers the event mechanism in a timer
routine. If you had no interrupt at all, you could set
irq to UIO_IRQ_NONE, though this
rarely makes sense.
unsigned long irq_flags: Required if you've set
irq to a hardware interrupt number. The flags given
here will be used in the call to request_irq().
int (*mmap)(struct uio_info *info, struct vm_area_struct
*vma): Optional. If you need a special
mmap() function, you can set it here. If this
pointer is not NULL, your mmap() will be called
instead of the built-in one.
int (*open)(struct uio_info *info, struct inode *inode)
: Optional. You might want to have your own
open(), e.g. to enable interrupts only when your
device is actually used.
int (*release)(struct uio_info *info, struct inode *inode)
: Optional. If you define your own
open(), you will probably also want a custom
release() function.
Usually, your device will have one or more memory regions that can be mapped
to user space. For each region, you have to set up a
struct uio_mem in the mem[] array.
Here's a description of the fields of struct uio_mem:
int memtype: Required if the mapping is used. Set this to
UIO_MEM_PHYS if you you have physical memory on your
card to be mapped. Use UIO_MEM_LOGICAL for logical
memory (e.g. allocated with kmalloc()). There's also
UIO_MEM_VIRTUAL for virtual memory.
unsigned long addr: Required if the mapping is used.
Fill in the address of your memory block. This address is the one that
appears in sysfs.
unsigned long size: Fill in the size of the
memory block that addr points to. If size
is zero, the mapping is considered unused. Note that you
must initialize size with zero for
all unused mappings.
void *internal_addr: If you have to access this memory
region from within your kernel module, you will want to map it internally by
using something like ioremap(). Addresses
returned by this function cannot be mapped to user space, so you must not
store it in addr. Use internal_addr
instead to remember such an address.
Please do not touch the kobj element of
struct uio_mem! It is used by the UIO framework
to set up sysfs files for this mapping. Simply leave it alone.
Adding an interrupt handler
What you need to do in your interrupt handler depends on your
hardware and on how you want to handle it. You should try to
keep the amount of code in your kernel interrupt handler low.
If your hardware requires no action that you
have to perform after each interrupt,
then your handler can be empty. If, on the other
hand, your hardware needs some action to
be performed after each interrupt, then you
must do it in your kernel module. Note
that you cannot rely on the userspace part of your driver. Your
userspace program can terminate at any time, possibly leaving
your hardware in a state where proper interrupt handling is
still required.
There might also be applications where you want to read data
from your hardware at each interrupt and buffer it in a piece
of kernel memory you've allocated for that purpose. With this
technique you could avoid loss of data if your userspace
program misses an interrupt.
A note on shared interrupts: Your driver should support
interrupt sharing whenever this is possible. It is possible if
and only if your driver can detect whether your hardware has
triggered the interrupt or not. This is usually done by looking
at an interrupt status register. If your driver sees that the
IRQ bit is actually set, it will perform its actions, and the
handler returns IRQ_HANDLED. If the driver detects that it was
not your hardware that caused the interrupt, it will do nothing
and return IRQ_NONE, allowing the kernel to call the next
possible interrupt handler.
If you decide not to support shared interrupts, your card
won't work in computers with no free interrupts. As this
frequently happens on the PC platform, you can save yourself a
lot of trouble by supporting interrupt sharing.
Writing a driver in userspace
Once you have a working kernel module for your hardware, you can
write the userspace part of your driver. You don't need any special
libraries, your driver can be written in any reasonable language,
you can use floating point numbers and so on. In short, you can
use all the tools and libraries you'd normally use for writing a
userspace application.
Getting information about your UIO device
Information about all UIO devices is available in sysfs. The
first thing you should do in your driver is check
name and version to
make sure your talking to the right device and that its kernel
driver has the version you expect.
You should also make sure that the memory mapping you need
exists and has the size you expect.
There is a tool called lsuio that lists
UIO devices and their attributes. It is available here:
http://www.osadl.org/projects/downloads/UIO/user/
With lsuio you can quickly check if your
kernel module is loaded and which attributes it exports.
Have a look at the manpage for details.
The source code of lsuio can serve as an
example for getting information about an UIO device.
The file uio_helper.c contains a lot of
functions you could use in your userspace driver code.
mmap() device memory
After you made sure you've got the right device with the
memory mappings you need, all you have to do is to call
mmap() to map the device's memory
to userspace.
The parameter offset of the
mmap() call has a special meaning
for UIO devices: It is used to select which mapping of
your device you want to map. To map the memory of
mapping N, you have to use N times the page size as
your offset:
offset = N * getpagesize();
N starts from zero, so if you've got only one memory
range to map, set offset = 0.
A drawback of this technique is that memory is always
mapped beginning with its start address.
Waiting for interrupts
After you successfully mapped your devices memory, you
can access it like an ordinary array. Usually, you will
perform some initialization. After that, your hardware
starts working and will generate an interrupt as soon
as it's finished, has some data available, or needs your
attention because an error occured.
/dev/uioX is a read-only file. A
read() will always block until an
interrupt occurs. There is only one legal value for the
count parameter of
read(), and that is the size of a
signed 32 bit integer (4). Any other value for
count causes read()
to fail. The signed 32 bit integer read is the interrupt
count of your device. If the value is one more than the value
you read the last time, everything is OK. If the difference
is greater than one, you missed interrupts.
You can also use select() on
/dev/uioX.
Further information
OSADL homepage.
Linutronix homepage.